ARCHES IN STEEL
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GENERAL FEATURES. STRUCTURAL SYSTEMS ADOPTED IN ARCH DESIGN
A. IMPORTANT ADVANTAGES OF ARCHES
•Large spans – in average 80...100 m;
•Low weight- economy in the steel consumption;
•Appreciated aesthetics in modern architecture;
•Favorable mechanism;
•Efficient production-use of standard sections on large scale;
•Large possibilities of using advanced computer aided design tools.
B. DIFFICULTIES IN THE DESIGN
•Lack of specific rules for design in the international steel codes;
•The instability may be a major criteria in arches design.
Olyimpic Stad-Athens Hassel Ethias
Santiago Calatrava’s Bilbao footbridge, Bilbao
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Implications of the static system adopted
Free standing arch: bigger deformations; intricate constructive details for the arch and for the roof in the crown of the arch (rarely used). Doubly articulated arch: simple execution; not influenced by the variations of temperature and the sunk of the supports; the disadvantage is related to un-rational distribution of bending moments along the arch line. Arch encased in the foundations: increased stiffness; more rational distribution of the bending moments along the arch line; needs stronger foundations and the whole system is sensible to ground sinking (settlements at the foundation level); a solution for weak soils- arch with sag-rod.
Static structures adopted: a- static determinate: free standing arch; b- hyper-static structures: 1) double hinged arch; 2) fully restraint ; 3) rigid connections in foundations and articulation at the key stone; 4) fixed or doubly hinged with sag-rod.
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SOLUTIONS ADOPTED FOR THE DESIGN OF STEEL ARCHES
Various systems of lattice systems adopted for the cross section of arches
Solutions for arches in steel with great spans and heights
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SHAPES OF THE ARCHES
xpy 22
chxee
yxx
2
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• Parabola - drawn on the coincidence curved line of the uniform distributed load acting on a horizontal line.
• A very small ratio between the deflection and the span - parabola replaced by an arc of circle without a significant modification on the internal efforts (mostly the bending moments). Arc of circle is preferred from the point of view of assembling and mounting.
• Stability criteria: The neutral axis of the arch must be situated between the two pressure curves modeled by wind pressure; otherwise special measures to insure the stability of the arch must be provided (both extreme fibers are in compression).
The deformations of N. A. of arches under wind pressure
SHAPES OF THE ARCHES
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In the figure above:
a - hot-rolled cross section, beam or box;
b – lattice beam, simply or double walled
Cross section is constant; variation is adopted in the case of very important spans. Shape of the arch is rarely designed in a continuous line; generally is a polygonal line (several linear prefabricated units assembled in site of 6…9 m length).
Heights of the cross section of arches depend on the solution adopted:
-arches with beam cross section: h= (1/50....1/80)l
-arches made of lattice systems: h= (1/30....1/60)l; the internal system adopted is triangular with or without struts with the angle between the ties and the chord 400...500
Plate girder is a solution sensitive to local buckling of the web under big axial efforts – thick webs and transversal stiffeners.
Steel sections used for arches
Geometry of the internal members f the arches; a)- triangular system; b)- triangular system with struts
CONSTRUCTIVE DETAILS
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Classic solution:
The roof cladding lays directly on the top chord of arches (LT=4...6 m) or on purlins (LT=6...12 m);.
Longitudinal and transversal bracing insure the collaboration between arches for the effects of wind action and a general stiffness against lateral instability;
Purlins: hot-rolled sections, Castella beams, lattice girders; braces connected between the bottom flanges or bottom chords of purlins and bottom flanges or bottom chords of laced arches insure lateral stability.
Connections between the purlins and the arch elements: a)- arches made of trusses; b)- arches made of plate girder sections
Purlins placed normal to the axis or the arch: they must be interconnected with diagonals when the roof cover is
not rigid enough or not fixed continuously
CONSTRUCTIVE DETAILS
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POSSIBILITIES OF PLACING THE PURLINS IN THE CLASSIC SOLUTION
Position of purlins in the roof: a)- in vertical plane; b)- normal to the axis of the arch
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SOLUTION OF PURLINS WITH RIBS
• Purlins placed normal to the N.A.: I - weight of the roof cladding and snow transferred to purlins and to the structure of arch; II- the tangent force in the plane of the roof (from self-weight and snow action) is taken by the ribs. • Ribs are multi-hinged arches; they collect the transversal forces from the crown of the arch to the supports and sometimes the ribs have their own foundations. •The force normal to the plane of the roof is taken by the purlins. •Purlins placed gravitational: •Very difficult details of supports and fixing; •Difficult laying the roofing.
Forces transmitted to the ribs
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The two arches and the transversal bracing act as space rigid frames.
MODERN SOLUTIONS: COUPLED ARCHES BRACED TRANSVERSALLY
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MODERN SOLUTIONS: COUPLED ARCHES AND CANTILEVERED PURLINS
The end parts of the purlins are knee braced and they are parts of the longitudinal bracing in the plane of the roof.
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BRACING SYSTEM OF ARCHES
Bracing system for the classic solution adopted
for the structure of arches
Bracing system for the solution with coupled arches
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DESIGN OF THE HINGES ON THE SUPPORTS AND IN APEX
Hinges in the supports of arches: a)- with plates; b), c)- knee; d)- swing support
Hinges in the apex: a), b)- with plates; c)- bolted; d)- with splices; e)- swing support
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SPECIFIC PROBLEMS IN THE STRUCTURAL COMPUTATION OF ARCHES
Coefficients of the snow deposit on the roof and wind pressure on the structure of an arch
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DOUBLE HINGED ARCH-MOST FREQUENT SOLUTION
Equilibrium of forces in hyper-static arches: a)- double hinge arch; b)- double hinged with tie-rod
Arch with parabolic shape
Variation of temperature in the N. A of the arch
01 PX
cos1;1
22
1
nym
EA
dsn
EI
dsm
EA
dsnN
EI
dsmMP
00
iiA PxVM 0
sinsin0 iA PVNcos0
0
XNN
yXMM
01
t
PAE
lXX
0
cos8cos
8
2
2
M
f
lqXN
f
lqX
l
dsEI
y
tlX
0
2
l
l
dsEI
y
dsEI
yM
X
0
2
0
0
h
tIEEIM 1
0
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AXIAL FORCES IN THE MEMBERS OF THE LACED ARCH
Arch Values of for l/f equal with
0.05 0.2 0.3 0.4 0.5
With 3 hinges 1.2 1.2 1.22 1.35 1.48
With 2 hinges 1.00 1.10 1.22 1.35 1.48
Fully restraint 0.70 0.75 0.80 0.85 0.90
Axial forces in the internal members of the arch
Instability patterns of arches
The verifications regarding instability are: -verifications for lateral or flexural-torsional buckling; -verifications for overall buckling. critical axial force (Euler):
22 / sEINcr
s- equal with half of the arch length; in the case when the ratio l/f<5 (l, the span of the arch and f, the height), s will be considered equal with l. - - tabulated values depending on the end restraints of the arch (see table) and also on the ratio l/f.
Table 6. Values of the amplifying factor
cos
TD
h
M
hNN
h
M
hNN
ii
ss
2sin
d
is
is AAA
NND
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AXIAL FORCES IN THE TRANSVERSAL BRACING
Forces in the internal members of the transversal bracing (wind on the gable)
iiiiii
i
i
iiii
tgTDNN
TDTD
sin
cos
1111
11
coscos
iiiiiii
iii
WDDTT
WTT
i
ji WWT1
2/
1
1
1 2/i
ji WWT
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DETAILS OF CONSTRUCTION-ARCHES WORLDWIDE
Foot springs
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Arches of smaller dimensions with different destinations : agriculture, commerce, light industry
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Olympic Sports Structures-Athens
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Roofs for great stadiums
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Churches
Airport Terminal Chek Lap Kok-Corea
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Chicago Railway Station Terminal
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