GreischGeneral studies - Millau Viaduct An eight-span multi-cable-stayed viaduct of overall length...
Transcript of GreischGeneral studies - Millau Viaduct An eight-span multi-cable-stayed viaduct of overall length...
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GreischDesign with FINELGN
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Liège Science ParkAllée des noisetiers 25B-4031 Liège, Belgique
+ 32 (0)4 366 16 [email protected]
LuxembourgParc d’Activités Capellen 2-4, bât. BL-8308 Capellen, GD Luxembourg
+ 32 (0)4 366 16 [email protected]
Omega CourtRue Jules Cockx 8-10B-1160 Bruxelles, Belgique
+ 32 (0)2 778 97 [email protected]
www.greisch.com
London
Paris
Bruxelles
Lille
Luxembourg
Köln
Liège
Rotterdam 150 km
310 km 1h30
170 km
370 km 2h00
210 km 2h00
100 km
Amsterdam
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Greisch R&D DepartmentGreisch is based in Liège, and was founded in 1960 by the engineer and architect René Greisch. With its architects company, Greisch gathers nearly two hundreds collaborators. The team is always open to collaborative ventures, and carries out complex assignments in the most varied fi elds. One of its assets is that at a very early stage, it established a working relationship with the University of Liège. The resulting cooperation has enabled links to be established between the university and businesses, and to make use of advanced researches to develop applications with construction companies. Within Greisch , seve-ral engineers are on the teaching staff of the Applied Science faculty, and themselves train engineers, and guide their research. Furthermore, Greisch ’s team includes a number of young engineers who are carrying out research into new fi elds. This is how Greisch is able to stay at the forefront of developments in computerisation and has a research unit which, under the name Greisch Ingénierie, develops software for the various assignments for which it is commissioned. Knowledge of the fabric of the fi rms and their potential in various fi elds is another asset enabling Greisch to work on the design of many highly inno-vative works, taking advantage of the techniques available, endeavouring to improve them still further or simplify their implementation, hence to reduce the cost of construction. The total integration of the techniques and constraints of implementation as well as innovative theoretical research, is the key to all the new approaches put forward by Greisch.
The beliefs of Greisch ’s founder about correctness of design in relation to effi ciency, economy and func-tionality have been realised in a series of works which have established the reputation and the references of Greisch . The interest of René Greisch in architecture just as much as in the dimensioning of buildings, has instilled the Greisch team with a spirit of research and innovation which has made its reputation among architects, and has led to many collaborative ventures with the most famous names. Greisch also has architects on its own staff, in order to create an atmosphere where the engineers are constantly ques-tioning and searching for new solutions, both formal and technical. The team spirit and the attitude of quest, the determination to work through collaboration and synergy, constant innovation and dynamism, invention combined with imagination have become the working methods and principles that underpin the work of Greisch .
This research culture that has developed within Greisch and the presence of very sophisticated computer equipment enables it to move into new fi elds, and devote the time necessary to discover original solutions in the most varied fi elds: stadium roof, ultra-light canopy, telecommunications aerial, where the search for the greatest structural economy guides our invention. The discretion of our work, the absence of a demonstrative character, the economic use of resources, the search for a kind of self-evident simplicity of structure form the basic principles of the attitude of Greisch when dealing with these projects, and also form part of the team’s culture. The art of the engineer lies in eschewing the desire to demonstrate how clever an invention is, so that a non-expert fi nds it almost obvious when it fulfi ls its function, and being careful not to show off all the amazing feats of which it is capable.
Exterior view and interior ambiances of the Greisch offi ce
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FINELGFINELG program is a nonlinear software based on finite elements method. Several calculations of a given structure can be undertaken : - its linear behaviour ; - its eigenfrequencies and associated vibration modes taking into account or not the internal stresses ; - its critical buckling loads and its associated instability modes taking into account or not the non-linea-
rities ; - its «effective» behaviour until (and after) collapse.
For the study of the actual behaviour of the structure, different non-linear effects can be considered : - large displacements, instabilities (local buckling of shell, buckling, bending and torsional buckling, late-
ral torsional buckling of beams) ; - elasto-plastic constitutive laws for steel ; - nonlinear constitutive laws for concrete with cracking, creep and shrinkage ; - residual stresses ; - semi-rigid joints ; - initial deformations.
FINELG has a very complete library of finite elements to analyse civil engineer structures : truss bars, cables, plane beams, spatial beams, plates, shells, non-linear springs, non-linear supports, linear or non-linear constraints.
Available elasto-plastic constitutive laws cover the engineer needs for steel, concrete or composite struc-ture studies.
FINELG covers different domains of behaviour : - static ; - dynamic by modal or nodal analysis ; - spectral or step by step analysis for :
> seismic solicitations > turbulent wind loading
Moreover FINELG allows : - to undertake academic research in the domain of non-linear analysis ; - to simulate laboratory tested structures to better analyse the results obtained ; - to realise parametrical studies to define or to complete design rules ; - to verify structures or part of complicated structures for which simple calculation methods do not exist.
General studies - Millau Viaduct 2General studies - Third Bosphorus bridge 8Dynamic behaviour - HST Viaducts 12HST Viaducts - fatigue 14Bridge - Instability 16Patch loading studies 21Fluvial and maritime structures 24
Footbridge - dynamics 26Expertise 27Large roofs 28Wind engineering 36Pylons 38Special structures 39Restoration 40
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General studies - Millau Viaduct
An eight-span multi-cable-stayed viaduct of overall length 2,460 metres, in a site presenting severe geo-graphical and climatic conditions: a steep-sided valley, and strong winds with high speeds and turbulence.
The superstructure is entirely of steel – an orthotropic deck (28 m wide and 4.20 m high) and 7 pylons (90 m high). Total weight of steel: 50,000 tonnes.
The bridge was built by launching the deck from the two sides of the valley, earning a triple world record – launched in spans of 171 m, to a maximum height of 280 m (junction over the river Tarn) and with a total weight 20,000 tonnes on the last launch. The highest temporary pier stood at 175 m.
Greisch introduced a steel variant and carried out all the working calculations for the deck-pylon-cable structures for :
- the service life ; - each construction stages ; - under static and turbulent wind.
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Deformed shape of deck during launching
Deformed shape simulation
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Verification of the patch loading effect
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For the lauching, translators were located at the top of the piers.
These tools were able to move the deck on a distance of 600 mm in about four minutes.
Deck on the runner wedge
Deck on the rigid frame of the translator
Simulation of the wedge deformations during a launching step
View of the translator
Lifting wedge
Runner wedge
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Study of the local stresses distribu-tion in the node deck / pylon / pier.
3D model of the connection deck / pylon / pier
Model of one launching step
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Nonlinear simulations of the launching steps.
Vibration eigen modes
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General studies - Third Bosphorus bridge
Suspension bridge with a 1408 m long main span and a total length of 2 408 m, located at the north of Istanbul near the Black Sea.
As the Brooklyn bridge, the main span is partially suspended at the towers by stiffening cables and at the main cables with vertical hangers. The top of the towers, composed of 2 concrete shafts, are 320 m above sea level. The deck is 5,50 m high and 58 m wide with 4 road lanes in each direction, 2 railways tracks and 2 sidewalks.
In the central span, the steel deck is made up of an orthotropic plate (total steel weight : 45 000 tons). The side spans are made up of post-tensionned concrete.
The preliminary design is the result of a competition won by Michel Virlogeux (France) and Jean-François Klein (Switzerland). The final design is made by T-Ingénierie (Switzerland) and Greisch (Belgium) on behalf of the joint venture Içtas and Astaldi S.P.a.
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Greisch mission :
- the global calculations of the structure during its service life ;
- proposals for construction methods ; - the design of the steel deck in the main span ; - the dynamic studies necessary to verify the
behaviour of the global structure :
- under the wind (during the service life and the construction stages - verifications made with numerical simulations and by tests in wind tun-nel laboratory),
- under the earthquake and/or the passages of trains.
0,17 Hz
0,29 Hz
Wind tunnel tests
Beam model and vibration eigen modes
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Models of the deck
Accelerogram for seismic simulation
Deformed shapes during earthqake
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Some steps of the main span construction
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Dynamic behaviour - HST Viaducts
Lots of high speed train viaducts are made up of steel or composite (steel and concrete) structure. The high density of such railways in France gave us the opportunity to collaborate with several contractors in the construction of them.
The first mission, in 1992, lead us to fulfill the detailed design of the longest French viaduct (Saint-Omer - La Haute Colme). It is a dual girder bridge from which we learned the technical railway bridges specifica-tions, which include the dynamic and fatigue specific behaviours.
Later in the 90’s, we were called by the SNCF, through the contractors, to make the detailed design of the four most prestigious steel bridges along the new high speed line between Lyon and Marseille : Arc, Donzère (Garde-Adhémar), Mornas and Mondragon.
The viaduct over the river Sado in Portugal, has a quite different history, as we collaborate with a Portu-guese engineering office for the full design of the multiple arch bridges, up to the detail design.
Sado Viaduct (Portugal)
Vibration eigen mode
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Arc Viaduct - 2,89 Hz
La Haute-Colme (Saint-Omer - France)
Vibration eigen mode
Global FE model of Arc Viaduct (Aix en Provence - France)
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HST Viaducts - fatigue
FE model of Mornas Viaduct Accelaration versus train speed
Pulvermühlen viaduct (Luxembourg) Fatigue analysis of one node
Axelstainless
Ringstainless
Chape cast steel
Gap
HangerCollapse
Plastificationschema Contour lines of stresses
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Fatigue analysis of one node
Stresses distribution inside a frame connection
Test and models of hanger sockets
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Bridge - Instability
Eau-Rouge Viaduct (belgium)
Instability mode
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Instability modes
Milsaucy bridge (Belgium)
Hermalle Bridge (Belgium)
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European bridge (Coimbra - Portugal)
Vibration eigen modes
Analysis of the behaviour during the construction : cantilever method / composite deck
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0,63 Hz
European bridge (Coimbra - Portugal)
Vibration eigen modes
Ravine-Fontaine bridge (Island Reunion - France)
Analysis of the behaviour during the construction : cantilever method / composite deck (with creep, shrinkage, cracking of concrete)
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Arch bridge (Chooz - France)
Vibration eigen modes
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Patch loading studies
Instabilty mode Measurements on work site
Plastification schema Stresses distribution
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Sado viaduct (Portugal)
Vertical reactions versus web lateral displacement
Interaction criteria : bending moment / vertical reaction
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Instability mode
Schengen Viaduct (Luxembourg)
Plastification schema
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Fluvial and maritime structures
Gate of the Lanaye lock
Stresses distribution in the transversal beams : without / with reinforcement
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Blankenberge Pier (Belgium)
Blankenberge Pier, a unique example on the North Sea, has undergone major renovation/refurbishment to provide new facilities.
The extremely complex works, including underpinning of part of the existing building and the creation of new spaces in the tidal zone with the problem of resisting to the effect of tides.
Global model
Test in a hydraulic lab
Piles wall model
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Footbridge - dynamics
Tuned mass damper (TMD)
Dynamic tests
Bridge response with TMD
Hoge Brug - Maastricht (Nederland)
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Expertise
Hoge Brug - Maastricht (Nederland)
Simulation of the collapse
Global model
Collapse of the Terminal 2E (Roissy - France)
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Large roofs
Canopies models
Louis Vuitton Foundation (Paris - France)
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Stresses distribution in the connection between the arch, longitudinal beam and the support beam
Guillemins railway station (Liège - Belgium)
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Lille stadium (France)
Instability mode of the mega-truss
Global model
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X
714
21
28
35
42
50
57
64
71
78
85
92
100
Buckling of one cover plate
Instability mode of the mega-truss
Plastification schema in the cover plate
Member Connections with single axel
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Deformed shape
Plastification schema at collapse
King Baudouin stadium (Bruxelles - Belgium)
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Knokke Hospital (Belgium)
3D model of the main slab
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Paradis tower (Liège - Belgium) 120 m
Abidjan (Ivory Coast) 280 m
Central core models
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Solar power plant (Atacama - Chile)
Steel receiver models
Concrete tower eigen mode
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Wind engineering
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Frequency
DSPmodal force
Frequency
Transfertfonction
nk nk
k
Frequency
Response
2
-1
-0,5
0,5
CD
CL
CMWindincidence (°)
-10 -8 -6 -4 -2 2 4 6 8 10
Frequency
DSPmodal force
Frequency
Transfertfonction
nk nk
k
Frequency
Response
2
-1
-0,5
0,5
CD
CL
CMWindincidence (°)
-10 -8 -6 -4 -2 2 4 6 8 10
TURBULENT WIND with FINELG (FEM software)Structure behaviour under wind loading :+ wind characteristics (turbulence intensities, turbulence scales, coherence factors, ...) + aerodynamiccoefficients+ numerical simulations = wind responses mean + background + resonant
Guillemins Station (Liège - Belgium)
Vibrations modes
RWTH
Millau Viaduct (France)
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Bosphorus Bridge (Turkey)Wind tunnel tests
ULg
Polimi
Lille Arena (France)Wind tunnel tests and numerical simulations
CSTB
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Pylons
Simulation of transmission tower collapse
Transmission tower : instability mode and plastification schema at collapseVibration mode of one telecommunication tower
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Water Tower (Ghlin - Belgium)
Special structures
Erection modelisation of a circus tent Arsenic company (Liège - Belgium)
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Greisch R&D DepartmentGreisch is based in Liège, and was founded in 1960 by the engineer and architect René Greisch. With its architects company, Greisch gathers nearly two hundreds collaborators. The team is always open to collaborative ventures, and carries out complex assignments in the most varied fi elds. One of its assets is that at a very early stage, it established a working relationship with the University of Liège. The resulting cooperation has enabled links to be established between the university and businesses, and to make use of advanced researches to develop applications with construction companies. Within Greisch , seve-ral engineers are on the teaching staff of the Applied Science faculty, and themselves train engineers, and guide their research. Furthermore, Greisch ’s team includes a number of young engineers who are carrying out research into new fi elds. This is how Greisch is able to stay at the forefront of developments in computerisation and has a research unit which, under the name Greisch Ingénierie, develops software for the various assignments for which it is commissioned. Knowledge of the fabric of the fi rms and their potential in various fi elds is another asset enabling Greisch to work on the design of many highly inno-vative works, taking advantage of the techniques available, endeavouring to improve them still further or simplify their implementation, hence to reduce the cost of construction. The total integration of the techniques and constraints of implementation as well as innovative theoretical research, is the key to all the new approaches put forward by Greisch.
The beliefs of Greisch ’s founder about correctness of design in relation to effi ciency, economy and func-tionality have been realised in a series of works which have established the reputation and the references of Greisch . The interest of René Greisch in architecture just as much as in the dimensioning of buildings, has instilled the Greisch team with a spirit of research and innovation which has made its reputation among architects, and has led to many collaborative ventures with the most famous names. Greisch also has architects on its own staff, in order to create an atmosphere where the engineers are constantly ques-tioning and searching for new solutions, both formal and technical. The team spirit and the attitude of quest, the determination to work through collaboration and synergy, constant innovation and dynamism, invention combined with imagination have become the working methods and principles that underpin the work of Greisch .
This research culture that has developed within Greisch and the presence of very sophisticated computer equipment enables it to move into new fi elds, and devote the time necessary to discover original solutions in the most varied fi elds: stadium roof, ultra-light canopy, telecommunications aerial, where the search for the greatest structural economy guides our invention. The discretion of our work, the absence of a demonstrative character, the economic use of resources, the search for a kind of self-evident simplicity of structure form the basic principles of the attitude of Greisch when dealing with these projects, and also form part of the team’s culture. The art of the engineer lies in eschewing the desire to demonstrate how clever an invention is, so that a non-expert fi nds it almost obvious when it fulfi ls its function, and being careful not to show off all the amazing feats of which it is capable.
Exterior view and interior ambiances of the Greisch offi ce
Restoration
Aulne Abbey (Belgium)
Tournai Cathedral (Belgium)
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Greisch R&D DepartmentGreisch is based in Liège, and was founded in 1960 by the engineer and architect René Greisch. With its architects company, Greisch gathers nearly two hundreds collaborators. The team is always open to collaborative ventures, and carries out complex assignments in the most varied fi elds. One of its assets is that at a very early stage, it established a working relationship with the University of Liège. The resulting cooperation has enabled links to be established between the university and businesses, and to make use of advanced researches to develop applications with construction companies. Within Greisch , seve-ral engineers are on the teaching staff of the Applied Science faculty, and themselves train engineers, and guide their research. Furthermore, Greisch ’s team includes a number of young engineers who are carrying out research into new fi elds. This is how Greisch is able to stay at the forefront of developments in computerisation and has a research unit which, under the name Greisch Ingénierie, develops software for the various assignments for which it is commissioned. Knowledge of the fabric of the fi rms and their potential in various fi elds is another asset enabling Greisch to work on the design of many highly inno-vative works, taking advantage of the techniques available, endeavouring to improve them still further or simplify their implementation, hence to reduce the cost of construction. The total integration of the techniques and constraints of implementation as well as innovative theoretical research, is the key to all the new approaches put forward by Greisch.
The beliefs of Greisch ’s founder about correctness of design in relation to effi ciency, economy and func-tionality have been realised in a series of works which have established the reputation and the references of Greisch . The interest of René Greisch in architecture just as much as in the dimensioning of buildings, has instilled the Greisch team with a spirit of research and innovation which has made its reputation among architects, and has led to many collaborative ventures with the most famous names. Greisch also has architects on its own staff, in order to create an atmosphere where the engineers are constantly ques-tioning and searching for new solutions, both formal and technical. The team spirit and the attitude of quest, the determination to work through collaboration and synergy, constant innovation and dynamism, invention combined with imagination have become the working methods and principles that underpin the work of Greisch .
This research culture that has developed within Greisch and the presence of very sophisticated computer equipment enables it to move into new fi elds, and devote the time necessary to discover original solutions in the most varied fi elds: stadium roof, ultra-light canopy, telecommunications aerial, where the search for the greatest structural economy guides our invention. The discretion of our work, the absence of a demonstrative character, the economic use of resources, the search for a kind of self-evident simplicity of structure form the basic principles of the attitude of Greisch when dealing with these projects, and also form part of the team’s culture. The art of the engineer lies in eschewing the desire to demonstrate how clever an invention is, so that a non-expert fi nds it almost obvious when it fulfi ls its function, and being careful not to show off all the amazing feats of which it is capable.
Exterior view and interior ambiances of the Greisch offi ce
Aulne Abbey (Belgium)
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GreischDesign with FINELGN
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Desi
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Liège Science ParkAllée des noisetiers 25B-4031 Liège, Belgique
+ 32 (0)4 366 16 [email protected]
LuxembourgParc d’Activités Capellen 2-4, bât. BL-8308 Capellen, GD Luxembourg
+ 32 (0)4 366 16 [email protected]
Omega CourtRue Jules Cockx 8-10B-1160 Bruxelles, Belgique
+ 32 (0)2 778 97 [email protected]
www.greisch.com
London
Paris
Bruxelles
Lille
Luxembourg
Köln
Liège
Rotterdam 150 km
310 km 1h30
170 km
370 km 2h00
210 km 2h00
100 km
Amsterdam