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Introduction to Timber Roof Trusses

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Title: Introduction to Timber Roof Trusses


1
Introduction to Timber Roof Trusses
  • Whats in this presentation
  • Spanning between supports
  • Rafters the traditional approach
  • Trusses - a relatively new and efficient approach
  • Trusses use axially loaded members
  • A basic example of truss design
  • Joining triangles to make advanced truss designs
  • Making truss joints using nail plates
  • Truss terms
  • Truss types
  • Using trusses to make three dimensional shapes
  • Features of trusses that make better use of
    timber
  • Codes used in roof truss installation

2
Spanning Between Supports
  • Since our first attempts to enclose space for
    shelter, the most challenging process in building
    has been the carrying of loads over horizontal
    distances without touching the ground, ie.
    spanning between supports.
  • Because of scale effects, it can be quite
    challenging to span the distances encountered in
    buildings.

3
Rafters - The Traditional Approach
  • Possibly one of the first structures by which our
    species obtained shelter was to support a roof by
    spanning across walls using timber rafters acting
    as simple beams (framing for skillion roofs is
    still done this way).
  • As span increases so does beam size.
    Unfortunately, there are practical limits to the
    ability to continually increase beam size.

4
Trusses - a Relatively New and Efficient Approach
  • Manufactured timber roof trusses provide a
    structurally efficient alternative to timber
    beams. They place greater emphasis on axial
    loading of members and less on bending.
    Associated advantages of trusses include
  • Strong but light to erect
  • Can be made to suit most roof shapes
  • Less onsite fabrication, therefore less site
    labour and less effected by bad weather
  • Factory production allows automated production
  • Better quality control is possible
  • Trusses make maximum structural use of the timber
  • Trusses are capable of long spans
  • Internal walls are usually non-loadbearing
    therefore lighter weight internal walls are
    possible

5
Trusses Use Axially Loaded Members Instead of
Beams
  • Beams (e.g. rafters) are slender members which
    cope with loads - such as the weight of the roof
    - by resisting bending.
  • Beams are convenient but not efficient. For
    instance the easiest way to break a beam is to
    bend it in the middle until it snaps, not squash
    or stretch it from end to end. See which is the
    easiest by practising on a pencil.
  • Bending places load across the axis, while
    squashing (compression) and stretching (tension)
    place load along the axis. Axial loading is far
    more efficient than bending,
  • Truss members are designed by maximising axial
    loading and minimising bending.

Compression
Bending
Tension
6
A Basic Example of Truss Design using axially
loaded members
  • Traditional roofing materials such as thatch and
    shingles are not waterproof - they require steep
    pitches to shed water.
  • As the pitch of the roof increases, the rafters
    feel more axial load and less bending load. This
    is because the load increasingly runs down the
    rafter (thus compressing it) rather than running
    across it like a beam.
  • Roofs of this type were often constructed with a
    load bearing ridge beam

7
  • Coupled rafters lean on each other at the top and
    obviate the need for a load bearing ridge. At
    the bottom however, the axial thrust down the
    rafters tends to spread the walls outwards. In
    traditional construction, large buttresses were
    used to stop this spread from happening

8
  • By adding a member tying the bottoms of the
    coupled rafters to prevent them spreading the
    walls apart, a simple triangular truss is formed
    i.e. the rafters are in compression the tie
    member is in tension beam action in all members
    is minimal.
  • The underlying concepts in the example have since
    been used in advanced truss design, where axial
    loads are used to greater effect.

9
Joining Triangles to Make Advanced Truss Designs
Triangle doesnt change shape
  • Advanced truss designs build on the previous
    principles by adding many small triangles
    together, to make trusses capable of spanning
    long distances.
  • Triangles are good shapes because the joints in
    trusses are thought to act like hinges and
    triangles maintain a stable shape even when
    hinged joints are loaded. In contrast,
    rectangles move out of shape more easily.
  • Therefore the patterns of trusses tend to be made
    up of many triangles networked together.

Rectangle does
10
Holding Triangles Together with Nail Plates
  • Even though joints can usually be thought of as
    hinges, trusses depend a lot on their joints
  • This is challenging because of the different
    three dimensional properties in timber
  • The stress concentrations at single point joints
    such as bolts, cause problems as shown in the top
    sketch
  • Multiple-toothed nail plate connectors used in
    trusses, successfully deal with this by
    distributing the joint loads across a larger area.

11
  • The timber truss industry as we know it would
    not be possible without nail plate connectors
  • The plates are used in pairs - identical plates
    are pressed into each side of the joint using
    special equipment in a factory.

12
Truss Terminology
Top chord
Webs
Bottom chord
  • Given the previous discussion, a truss can be
    described as a pre-fabricated, engineered
    building component which functions as a
    structural support member.
  • There are different types of trusses but the same
    basic terms apply
  • Members are either top chords, bottom chords or
    webs
  • Each will be in tension or compression according
    to the type of truss involved

13
  • Bottom Chord
  • Defines the bottom member of the truss, usually
    horizontal, and carrying a combined tension and
    some bending stress (from gravity loads).

14
  • Top Chord
  • Defines the top members of the truss, usually
    sloping, and carrying combined compression and
    some bending stress (from gravity loads)

15
Web Webs are members joining top and bottom
chords to form a truss. They may be in tension or
compression depending on the truss design.
16
Apex The top point where two chords meet. This
can be either a Top Chord Apex or much less
commonly a Bottom Chord Apex (not shown). The Top
Chord Apex of multiple trusses in a row, forms
the ridge line of the roof.
17
Heel The point on a truss where the undersides of
the top and bottom chords join.
18
Panel points The points where web members and
chord members meet
19
Span The distance between the outer edges of the
load bearing walls supporting the trusses
(usually heel to heel)
20
  • Overhang Eaves OH
  • The parts of the top chords that extends beyond
    the intersection with the bottom chord (at the
    heel). This forms the eaves overhang of the
    roof.

21
Truss Types - Standard Trusses
Standard trusses conform to an outer triangular
shape typically resembling an isosceles triangle.
Many web layouts within the outer triangle are
used to address spanning ability, as follows
  • King Post has only one central vertical web.
    Used for small spans e.g. spans up to 5.0m.

 
Queen Post - two additional webs fanning outwards
from the base of the central web and connecting
to the middle of the top chords. Used for spans
up to 6.0m.   
22
A-Type - most common truss type but has no
central web. Instead, the truss span is divided
into three equal panel lengths with webs fanning
outwards from each . Spans up to 9.0m.
B-Type compared to the A-Type has 2 extra webs.
The panels points are also equally spaced. Spans
up to 14.0m
 
Standard girder can be based on any of the
previous types but is designed to be stronger to
support other trusses.
23
Truss Types for Hip Roofs
Hip end trusses include a variety of types
required to shape a hip end. The basic concept
is shown below then each type is discussed
individually
24
Truncated Standard Truss takes a standard truss
shape but cuts off the top to suit the slope at
the top of a hip end.
  • Truncated Girder Truss - is the main truss in a
    hip end. It occurs below the standard truncated
    trusses and takes the load of the outer hip
    trusses including the hip, jack and creeper
    trusses. It is made stronger than the standard
    truncated trusses to take these loads.

25
Hip Truss - forms the hip line of the roof. It
is similar to a half truss but with an extended
top chord extending over the truncated girder
truss and finishing as the top of the hip. Some
jack and all creeper trusses butt into it.
  • Jack Truss runs into the hip truss. It is also
    similar to a half truss but with an extended top
    chord extending over the truncated girder and
    meeting the hip truss.

Creeper Truss - runs into the hip truss with no
extension of the top chord i.e. stops short of
the truncated girder.
26
Other Truss Types
  • Scissor Truss - are modified standard trusses to
    suit a sloping ceiling. Most scissors have an
    equal pitch ceiling each side of the apex. Other
    ceiling lines are also possible

Bell Truss - a common roof shape for federation
and homestead style houses. The top chord has two
pitches, the lower pitch is usually over a
veranda or patio area.
Bowstring Truss - mostly used as a commercial
truss but becoming more common in the domestic
sector. The top chords are designed to allow a
curved roof
27
Variations to Truss Types
Cantilever Truss - can be any type of truss but
the support point on one or both sides is
located inside the span, not at the heel. An
extra web is required at the inner support
location(s).
Cut Off Truss - Can be any type of truss but does
not have a heel. This truss shape is determined
by the location and comparative height of the
pitching lines on either side of the roof area
Half Truss - A half truss is a full truss cut off
at the apex.
28
Using Trusses to Make Three Dimensional Roof
Shapes
  • The previous discussion identifies roof trusses
    as two-dimensional assemblies. These are added
    together to make three dimensional roof shapes.
  • To this end, trusses are usually spaced at
    regular intervals typically 600mm, 900mm or 1200
    apart, depending on the mass of the roofing
    material involved and local practise.
  • In making different shapes, a range of previous
    truss types may be configured to attain the
    required shapes. This, along with manufacturing
    and installation issues are discussed in greater
    detail under dedicated presentations.

29
Features of Trusses that Make Better Use of Timber
  • All types of engineered trusses improve upon
    certain short comings of roofs requiring large
    timber rafters and roof beams. Issues include
  • Timber roof member sags under bending and keep on
    sagging over the years - the bigger the span, the
    bigger the problem
  • Large, seasoned and clear timber sections are
    required to deal with sag issues but are
    expensive and increasingly hard to get

Large rafters Likely to sag (deflect)
30
  • Traditional roof designs try to reduce rafter
    spans using underpurlins and struts, but these
    may require large sizes and support is reliant on
    internal walls which arent always available.
    Large strutting beams must be used and as a
    result, sag and timber availability issues
    resurface.

31
  • Trusses are engineered to help in the following
    ways
  • Much lighter timber members can be used because
    the predominant actions are tension and
    compression, not bending
  • The lighter timber can be predominantly sourced
    from plantations and easily kiln dried so there
    are no surprises as they dry out
  • Deflections are much smaller, particularly in the
    long term
  • The roof frame can be planned and prefabricated
    off-site, making it more possible to take
    advantage of an engineered design

32
Putting the Camber into Trusses
  • During fabrication, trusses further improve on
    traditional rafter design by forcing an upward
    bend into the chords of trusses referred to as a
    Camber.
  • Camber helps to resist loads e.g. the amount of
    bend is calculated to help resist the load of
    tiles and ceiling lining. The calculations are
    designed to ensure the truss eventually flattens
    out to provide straight chords, once fully loaded.

33
Clear Spanning Internal Walls
  • A benefit of trusses is that they can span long
    distances in one go. External walls are usually
    used to provide support but internal walls are
    not needed.
  • Internal walls cause problems if used for
    support because they change the way the truss
    works. To prevent this
  • External load bearing walls are made slightly
    higher than internal walls, leaving a gap between
    the bottom chord and the internal wall
  • Special brackets fix the bottom chord to the
    internal wall the brackets allow the bottom
    chord to move up and down in the gap (but not
    sideways)

Click on the picture to watch a video
34
Codes used in Truss installation
  • Once trusses have been designed and manufactured
    according to previous engineering principles, the
    emphasis is on site installation practices
  • Australian Standard AS4440-2004 Installation of
    Nailplated Timber Trusses is the standard applied
  • It relates to residential construction (including
    BCA building classification 1,2,3 and 10) and
    light commercial structures.
  • It covers a broad variety of issues including
  • Terms and definitions
  • Installation techniques
  • Bracing requirements
  • Connection requirements
  • Eaves and gables
  • Lifting, storage and temporary bracing practices

35
  • Limits to the application of AS4440 include
  • Roofs with a maximum roof pitch of 45O
  • Roofs that are essentially rectangular layouts or
    a combination of rectangular elements
  • Roofs with a maximum truss span of 16m
  • Truss spacings at a maximum of 900mm for tiled
    roofs or 1200mm for metal sheet roofs
  • Nail plated trusses only
  • Maximum wind speeds - refer to either AS1170.2 or
    AS4055
  • Support documents linked to AS4440 include
  • AS1684 Residential Timber Framing Code
  • Installation manuals produced by individual truss
    manufacturers
  • Teaching resources in this package provide
    general information that draws on these sources.
    For specific advice, full detail must be obtained
    from the above documents.

36
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