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MATERIALS II

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MATERIALS II By Richard Cooper MATERIALS We will look at some aspects of :- Concrete Plastics Timber Also at:- Corrosion Cracks & Stress concentration Metals Metals ... – PowerPoint PPT presentation

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Title: MATERIALS II


1
MATERIALS II
  • By
  • Richard Cooper

2
MATERIALS
  • We will look at some aspects of -
  • Concrete
  • Plastics
  • Timber
  • Also at-
  • Corrosion
  • Cracks Stress concentration

3
Metals
  • Metals are not looked at specifically but covered
    by our discussions of environmental issues,
    corrosion and stress concentrations

4
Environmental Issues
5
  • About half the energy used in Britain goes on
    heating and lighting buildings and of this over
    half - 30 of the whole - is used in peoples
    homes.
  • A significant amount of energy is used in
    producing and transporting building materials and
    in the construction process itself.

6
  • This embodied energy accounts for a further 8
    of energy consumption.
  • A buildings embodied energy content can be cut
    by up to a half by adopting some simple measures

7
  • Use second-hand materials when possible, or
    materials with a high recycled content, in
    preference to new materials
  • Use minimally processed materials not highly
    manufactured products
  • Use locally produced materials not materials from
    far away or imported products

8
  • These simple measures are a start but do not take
    into account the other environmental effects of
    using building materials
  • The most commonly recognised approach to
    assessing materials is Life Cycle Analysis or LCA

9
  • LCA tracks the effect of materials through
    extraction, production, transport, construction,
    maintenance, repair, replacement and ultimate
    disposal
  • LCA underlies the Green Guide to Housing
    Specification
  • The Green Guide is published by the Building
    Research Establishment (BRE)

10
  • The Green Guide to Housing Specification analyses
    10 principal elements of a house - roof, external
    walls etc
  • Together these contribute around 90 of the
    overall environmental impacts of a house over a
    60-year life

11
Environmental Effects of Some Materials
12
Concrete, Brick
  • Pollution generated per kilogram by these
    materials is generally very low but they are used
    in large quantities,
  • This leads to the environmental problems
    associated with them
  • Energy used in transport
  • Damage to the landscape and environment arising
    from extraction and disposal

13
  • Recycling brick, stone and concrete for
    aggregates reduces environmental damage from
    extraction and waste disposal
  • Currently the maximum proportion of recycled
    aggregates to achieve the technical specification
    for concrete is around 20.

14
Cement
  • The production of cement is very
    energy-intensive.
  • Many cement factories use refuse-derived fuels
  • Poses a potential environmental threat because
    they produce dioxins and other pollutants

15
  • Portland cement is an almost universal product
    that enables concrete and high-strength
    load-bearing brickwork to be constructed
  • Cement mortar for brickwork prevents the bricks
    being re-used on demolition.
  • Lime mortars are far preferable as render and
    mortar for brickwork

16
Metals
  • Extraction of metals from ores is damaging to the
    environment and can release harmful substances.
  • Refining metals requires large amounts of energy
    but metals are relatively easy to recycle and
    this is generally economically attractive

17
  • Aluminium requires vast amounts of electrical
    energy to extract but can be recycled to produce
    high-grade materials
  • Steel can be recycled but to a lesser extent than
    aluminium

18
  • Steel needs coating to protect it but zinc
    coating in particular may cause environmental
    problems
  • Corrosion can be avoided by adding chromium and
    nickel to produce stainless steel
  • This process can, however, lead to emissions of
    these heavy metals which can be very
    environmentally damaging

19
  • Zinc stocks are expected to be severely depleted
    within decades at current rates of use
  • Extraction releases cadmium and other heavy
    metals
  • Zinc leaches into the environment from sheet zinc
    and galvanized surfaces
  • Zinc can be recycled but this is not economically
    viable at present.

20
  • Lead is in very limited supply
  • It is a hazardous material and its production and
    uses in paint and roofing produce pollution
  • Almost all sheet lead is recycled

21
  • Copper in pipes and on roofs causes pollution and
    can kill water organisms
  • Copper is long lasting and economically
    attractive to recycle, and this takes place on a
    large scale

22
Synthetics
  • The basic raw material is petroleum, the product
    of organisms that lived on earth many hundreds of
    thousands of years ago
  • For all practical purposes it is an irreplaceable
    resource
  • Extraction and transport have caused
    environmental disasters.

23
  • Refining and manufacture use energy, release
    organic hydrocarbons and create waste.
  • Synthetics do not generally cause problems during
    use but rather, after demolition.
  • Many synthetics can be recycled but the recycled
    material must be uncontaminated

24
  • Polyethylene and polypropylene are simple
    polymers whose production creates little
    pollution and uses relatively little energy
  • The additives used are relatively harmless.
  • The materials can be both recycled and
    incinerated.

25
  • PVC requires less energy to produce than many
    other synthetics but during its production,
    dioxins are created and released
  • PVC products must generally be either burned or
    buried at end of life
  • PVC can be recycled but in practice it contains
    such a variety of additives that uncontaminated
    high quality material is very hard to produce

26
  • Most other plastics have similar issues to those
    noted above
  • Many of the additives employed to enhance
    properties or reduce costs are also hazardous

27
Timber
  • This is the most important renewable raw material
    used in construction.
  • Production requires little energy and produces
    little pollution
  • The environmental effects arise from poor
    forestry management, preservative treatment and
    transport distance

28
  • Sustainable wood means wood from forests that are
    managed sustainably
  • Durable wood does not require treatment
  • Tropical wood from sustainable sources may have
    beneficial economic and social effects
  • Few sources of sustainable tropical wood exist.
    The only reliable guarantee is wood certified by
    the Forestry Stewardship Council (FSC)

29
  • Many forests are poorly managed
  • European forests tend to be better managed and
    are close to hand, but they produce relatively
    little durable wood
  • Timber can be very durable if the timber elements
    are carefully detailed to protect them from
    constantly moist conditions, and if maintenance
    is good.

30
  • Manufactured timber products (MDF, Chipboard etc)
    use bonding agents that generate pollution
  • Formaldehyde can be released into home
  • Hardboard and similar boards have low
    environmental impact as they are bonded at high
    pressure and temperature by the resins occurring
    naturally in the timber

31
  • Synthetic resin boards used for cladding take
    more energy to produce than other board materials
    and contain a high level of resin for bonding
  • They are, however, maintenance free and more
    resistant to impact damage than, for example,
    cement-bonded particleboard

32
Summary
  • The energy embodied in the construction of the
    home itself is a significant proportion of the
    total energy used and resulting emissions during
    the lifetime of a low-energy building.
  • It can be reduced by using materials that are-
    second-hand - minimally processed - locally
    produced.

33
  • Materials should be specified which have minimum
    environmental impacts.
  • This can be established by considering the Life
    Cycle Analysis of the material.

34
Cost Implications
  • Difficult to generalise.
  • Some materials with low environmental impact may
    cost more
  • Many cost less because they use fewer resources
    and are used in or near their natural state.

35
Benefits
  • Reduced environmental impacts from pollution, and
    less resource depletion.
  • The Green Guide to Housing Specification,
    Building Research Establishment Watford
  • Green Building Handbook, Volumes 1 2 by Woolley
    et al. (E FN Spon, London, 1997 and 2000)

36
Back To Materials Properties
37
CONCRETE
  • Made from Cement, Water Aggregate
  • Aggregates are most often stone such as river
    bed gravel, but may be crushed brick or reclaimed
    concrete. Can even be steel or lead shot or even
    polystyrene beads.

38
  • Cement may be Ordinary Portland Cement (OPC) or
    other special type suitable for the application
  • Water should be free from impurities

39
  • Concrete has low tensile strength and must be
    reinforced for use in any area that is in
    tension. This includes beams and lintels
  • Reinforcement is usually from steel bars but may
    be from glass or steel fibres
  • Corrosion of reinforcement can give major problems

40
  • Concrete has great strength in compression
    generally needing no reinforcement in that case
  • Concrete must be well compacted when wet to gain
    its full strength

41
  • Dense well compacted concrete can only be made
    with sufficient water in the mix
  • Excess water will reduce concrete strength
  • Determination of the correct quantity of water is
    very important
  • Never add more water to a truck mixer without
    proper authorization

42
  • Remember that concrete moves due to environmental
    changes
  • Increase in moisture or temperature will cause
    expansion which must be considered during design
    and properly dealt with during construction

43
PLASTICS
  • Three main groups
  • Thermoplastics
  • Lose rigidity when heated
  • Thermosetting plastics
  • Remain rigid when heated but will break down and
    char eventually

44
  • Elastomers
  • Thermosetting type with high elasticity but low
    modulus of elasticity

45
  • These are all organic compounds.
  • The molecules are long chains of atoms joined by
    strong covalent bonds. The way the chains join to
    each other is what gives the type of material

46
  • If the long chains are held by weak Van der
    Waals forces we have a thermoplastic
  • If the long chains are held by covalent bonds we
    have thermosetting plastics
  • If the long chains are coiled and twisted
    together held mainly with Van der Waals forces
    we have an elastomer

47
  • All of these plastics types are susceptible to
    degradation due to ultra violet radiation, heat
    radiation and solvent damage
  • They also suffer from large thermal movement

48
TIMBER
  • A natural material used both structurally and non
    structurally
  • Two main categories, hardwoods and softwoods.
    Though not all hardwoods are hard and not all
    softwoods are soft!
  • To ensure that you get the material you expect it
    is best to specify using the true botanical name

49
  • Properties of timber are mainly controlled by
    four things-
  • Density
  • The more dense the stronger, can be judged by
    counting the number of rings per 25mm
  • Moisture content
  • M/C will effect strength, susceptibility to
    fungal and insect attack and movement. Timber
    always tries to reach equilibrium with
    surroundings

50
  • Slope of grain
  • If the grain is parallel with the axis of the
    timber it has zero slope and strength is at max.
    As slope increases then strength reduces. A slope
    of 6 reduces strength by about 10
  • Defects
  • Mainly knots and splits, reduce strength in
    direct proportion to their size

51
  • For structural applications timber must be graded
  • Standards specify what is required but
    fundamentally two methods are used-
  • Mechanical stress grading or Visual stress
    grading

52
Specific Properties of Timber
  • Look at the material properties in the timber
    handout
  • The specific strength (strength divided by
    specific gravity) of timber is very good
  • Almost three times the specific tensile strength
    of common construction materials
  • If you want light and strong this is a good
    material

53
Specific Properties of Materials
54
CORROSION
  • This can give us major problems in construction
  • Nearly always caused by flow of electricity
    (electrons) between areas on a metal surface, or
    between different metals, through a fluid called
    an electrolyte

55
Anode Cathode Processes
56
  • These areas are known as anodes and cathodes
  • Corrosion always occurs at the anode
  • Anodes and cathodes can be formed by stress,
    surface imperfections, environmental conditions
    (flow of water for example) or by combining
    different metals

57
  • An electrolyte is almost always present in the
    form of moisture in the air which is (almost)
    always acidic

58
  • In neutral electrolytes corrosion slows and stops
    because hydrogen bubbles collect round the
    cathode and separate it from the electrolyte
    (Cathode polarization or The flat battery
    effect)
  • If oxygen is present it combines with the
    hydrogen and corrosion continues

59
  • Dissimilar metals in electrical contact will
    corrode in an electrolyte
  • A single metal in an electrolyte will corrode if
    anodic and cathodic areas are formed
  • If oxygen is present in the electrolyte then
    polarization will not be able to prevent
    corrosion

60
Preventing Corrosion
  • Dont mix dissimilar metals (Those that are far
    apart on the electrochemical series)
  • If you must mix metals then ensure that the
    cathode stays polarized by excluding oxygen
  • Coat metals to prevent the electrolyte touching
    the surface ( Paint, Metal coating)
  • Use a sacrificial anode

61
  • Any metal lower on the electro chemical series
    can be a sacrificial anode
  • Zinc is often used as in zinc coated corrugated
    roofing

62
The Electro Chemical Series
63
Typical Bimetallic Corrosion
64
CRACKS STRESS CONCENTRATIONS
  • Any discontinuity in a material in tension will
    cause a stress concentration out of all
    proportion to the loss of area
  • A round hole will increase stress by a factor of
    three at the edge of the hole
  • A crack may increase the local stress by a factor
    of ten or more. Hundreds for a sharp crack

65
Stress Concentration At Crack
66
  • Brittle materials (glass, concrete, iron) are
    very sensitive to cracks
  • Ductile materials (mild steel, copper, pure
    aluminium) can be safe even with long sharp
    cracks
  • Materials like timber, bone, plastics composites
    and other fibre reinforced materials can cope
    with cracks by using special crack stopping
    techniques

67
Toughening Effect of Fibres
68
  • Remember that even a small notch or defect can
    change a tough strong material into a dangerous
    brittle one

69
The Danger of Cracks
70
The End
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