Basis of Structural Design Arch → Truss

Basis of Structural Design Course 3 ... –economical design as longer members ... Bending and shear deformations in a truss Steel plate girder...

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Basis of Structural Design

Course 3 Structural action: trusses and beams

Course notes are available for download at http://www.ct.upt.ro/users/AurelStratan/

Arch



Truss

rafter

tie

Linear arch supporting a concentrated force: large spreading reactions at supports

Relieving of support spreading: adding a tie between the supports

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Truss forces  Truss members connected by pins: axial forces (direct stresses) only  Supports: – one pinned, allowing free rotations due to slight change of truss shape due to loading – one roller bearing support ("simple support") - allowing free rotations and lateral movement due to loading and change in temperature

- (C)

- (C) + (T)

 Forces in the truss: – tie is in tension (+) – rafters are in compression (-)

Truss forces  If more forces are present within the length of the rafter  bending stresses

 To avoid bending stresses, diagonal members and vertical posts can be added

-

+

+

-

+

 More diagonals and posts can be added for larger spans in order to avoid bending stresses

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Alternative shape of a truss  For a given loading find out the shape of a linear arch (parabolic shape)  Add a tie to relieve spreading of supports

 Highly unstable shape

Alternative shape of a truss  Add web bracing (diagonals and struts) in order to provide stability for the pinned upper chord members  If the shape of the truss corresponds to a linear arch web members are unstressed, but they are essential for stability of the truss  Reverse bowstring arches: – advantage: longer members are in tension – disadvantage: limited headroom underneath

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Truss shapes  Curved shape of the arch: difficult to fabricate  trusses with parallel chords  Trusses with parallel chords: web members (diagonals and struts) carry forces whatever the loads  Pratt truss: – top chord in compression – bottom chord and diagonals in tension – economical design as longer members (diagonals) are in tension

Truss shapes  Howe truss: – top chord in compression – bottom chord in tension – diagonals in compression

 Warren truss: – top chord in compression – bottom chord in tension – diagonals in tension and compression – economy of fabrication: all members are of the same length and joints have the same configuration

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Truss joints  Pinned joints  statically determinate structures  member forces can be determined from equilibrium only  Rigid joints  small bending stresses will be present, but which are negligible due to the triangular shape  Traditionally trusses are designed with pinned joints, even if members are connected rigidly between them

Space trusses  The most common plane truss consists of a series of triangles  The corresponding shape in three dimensions: tetrahedron (a)  The truss at (b) is a true space truss – theoretically economical in material – joints difficult to realise and expensive

 Two plane trusses braced with cross members are usually preferred

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Statically indeterminate trusses  Indeterminate trusses: large variety  Example (a): cross diagonals in the middle panel, so that one of the diagonals will always be in tension  Example (b): Sydney Harbour Bridge, Australia - both supports pinned

Beams  Beam: a structure that supports loads through its ability to resist bending stresses

 Leonardo da Vinci (1452-1519): the strength of a timber beam is proportional to the square of its depth

 Leonhard Euler and Daniel Bernoulli were the first to put together a useful theory around 1750

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Beams: analogy with trusses  Forces in a Pratt truss loaded by a unit central force

 Forces in a Howe truss

 Forces in a truss with double diagonals (reasonable estimate)

Beams: analogy with trusses  Chords: – The forces in the top and bottom chord members in any panel are equal, but of opposite signs, and they increase with the distance from the nearest support – Chords have to resist the bending moment, proportional to the distance from the nearest support

 Diagonals: – The forces in the diagonal members are equal, but opposite in sign, and have the same values in all panels – Diagonals have to resist the shear forces, the same in all panels

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Beams: analogy with trusses  Bending and shear deformations in a truss

Steel plate girder  Steel plate girder: heavy flanges and thin web welded together, and reinforced by transversal stiffeners  Unit vertical force at the midspan  Top flange: in compression  Bottom flange: tension  Web: shear, with principal tension and compression stresses similar to those in a truss  After web buckling, only tensile loads are resisted by the web, plate girder acting as a Pratt truss

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Beams: bending action  Top flange in compression linear variation of normal stress  Bottom flange in tension  Normal stress proportional to distance from the neutral plane  Simplifications: – Thin web, thick flanges  web has a small contribution to the bending resistance (ignore it) – Normal stress can be considered uniform on flanges

Beams: bending action  Moment resistance – Idealised double T beam: M = Ad/2 – Rectangular beam of the same area and depth: M = bd2/6 = Ad/6

 The best arrangement of material for bending resistance: away from the neutral axis

A/2



A/2

F =  ·(A/2)

d

d



F =  ·(A/2)

F =  ·(0.5d·b/2)

d

2d/3



A 

M =  ·A·d/2

M =  ·A·d/6

F =  ·(0.5d·b/2)

b

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Beams: bending action  Examples of efficient location of material for bending resistance – light roof beams (trusses)

– hot-rolled and welded girder

Beams: bending action  Examples of efficient location of material for bending resistance – panel construction

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Beams: bending action  Examples of efficient location of material for bending resistance – corrugated steel sheet

Beams: bending action  Examples of efficient location of material for bending resistance – castellated joist

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Beams: bending action  Examples of efficient location of material for bending resistance – columns requiring bending resistance in any direction: tubular sections

Beams: shear stresses  Simply supported beam of uniform rectangular crosssection loaded by a concentrated central force W: – can carry a moment M = bd2/6 – has a deflection 

 If the beam is cut in two parts along the neutral plane: – sliding takes place between the two overlapped beams – the two overlapped beams can carry a moment M = 2[b(d/2)2/6] = bd2/12, half of the uncut beam – the deflection of the two overlapped beams is 4

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Beams: shear stresses  In the uncut beam stresses should be present along the neutral plane to prevent sliding of the lower and upper halves of the beam: shear stresses  Smaller stresses would be required to keep the unity of action if the beam were cut above the neutral plane  Shear stresses – parabolic variation in a rectangular cross-section – carried mainly by the web, on which they can be considered to be constant for a steel double T beam

Structural shapes  Simply supported beam subjected to a uniformly distributed load

 The "perfect" use of material for bending resistance in a beam with idealised double T crosssection (M = Ad/2): parabolic variation of height

A/2

A/2

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Structural shapes  Simply supported truss subjected to a uniformly distributed load

 The "perfect" use of material for "bending" action: parabolic variation of height

Structural shapes  Bridge with a simply supported central span and two cantilevered sides  The shape of the truss must resemble the bending moment diagram in order to make efficient use of material in upper and bottom chords

 Quebec railway bridge

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Structural shapes

 Forth bridge, Scotland

 Anghel Saligny bridge, Romania

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