EXPO'98 PORTUGUESE NATIONAL PAVILION
A LARGE USE OF LIGHT WEIGHT STRUCTURAL CONCRETE
A. Segadães Tavares
Rui R. Vieira
ABSTRACT
The Portuguese National Pavilion is a special building that shall provide conditions for the
reception of delegations of most world nations that will be present at EXPO'98 - LISBON
INTERNATIONAL EXPOSITION.
The pavilion is a two bodied construction consisting of the main building and the canopy
which covers the Ceremonial Square housing official events.
The main building is a 4 storey multipurpose building roughly rectangular 90 meters long by
60 meters wide, with a inner courtyard. The structural solution of the building consists in
peripheral reinforced concrete shear walls starting from the basement walls and, in the
interior, in a steel framed structure with composite steel and light weight concrete slabs
allowing future rearrangement of the areas.
The canopy structure is a 20 centimetre thick parabolic membrane slab measuring in plan
approximately 65 meter by 50 meter and hanging from steel prestressed cables anchored
along the two short sides into anchorage slabs laying on the top of a reinforced concrete
structure of fins and shear walls. The use of light weight concrete provided a good way to
reduce that horizontal forces at the same time being adequate to provide the appropriate
strength and stiffness to assure the convenient distribution of thrust forces
Keywords: Canopy, Concrete, Presstress, Roof
A. Segadães Tavares, Civil Engineer, Chairman of STA, Segadães Tavares & Associados,
Lda, Portugal
Rui R. Vieira, Civil Engineer, Manager, LECA PORTUGAL, Argila Expandida, SA, Portugal
1. INTRODUCTION
Portugal being host of EXPO'98 - LISBON INTERNATIONAL EXPOSITION, the Portuguese
National Pavilion shall provide conditions for the reception of delegations of most world
nations that will be present on that event.
The pavilion is a two bodied construction consisting of the main building and the canopy. The
main building is a 3 storey multipurpose building 90 meters long by 60 meters wide, with a
inner courtyard, and during the EXPO'98 will house high quality reception facilities and the
exhibition of some interesting features of Portuguese history and after EXPO'98 will be used
as a museum or public offices. The canopy is a large roof covering the 75 meters long and
53 meters wide "Ceremonial Square" where the reception of delegations will be held.
Figure 1 - Main Façade of Portuguese National Pavilion at Waterfront
The structural solution of the building consists in peripheral reinforced concrete walls starting
from the basement walls that will provide the stability of the building against lateral forces
(wind and earthquake forces) and, in the interior, a steel framed structure with composite
steel and light weight concrete slabs allowing future rearrangement of the areas.
Figure 2 - Plan View of Canopy and Building
The canopy structure is a 20 centimetre thick parabolic membrane slab measuring in plan
approximately 65 meter by 50 meter and hanging from steel cables anchored along the two
short sides into anchorage slabs on the top of a reinforced concrete structure of fins and
shear walls. The small sag ( 3 meters against the 67.5 meters distance of supports) will
induce large horizontal thrust on the top of the fins. The use of light weight concrete provided
a good way to reduce that horizontal forces at the same time being adequate to provide the
appropriate strength and stiffness to assure the convenient distribution of thrust forces. That
was important to guaranty the 30 centimetres longitudinal slope for rain-water run-off, being
known that if it acted as in independent strips, one error of 1% in the cable force would cause
a deviation 10% of the longitudinal slope. Special study of the light weight concrete was
made to obtain the adequate strength and to achieve the construction of the membrane in
one only pour of concrete to avoid visible construction joints
2. GENERAL DESCRIPTION OF THE STRUCTURAL SOLUTION
2.1 The Building
The structure of the building should provide the possibility for easy major modifications of its
inside in a early future.
Starting from a basement floor with a raft foundation over concrete piles and surrounded by
reinforced concrete retaining walls, a mesh of concrete columns, spaced of 8 meters on
centre, supports the ground floor solid concrete slab.
Figure 3 - View from inside
From the ground floor starts a different kind of structure. On the periphery of the building
reinforced concrete shear walls give continuity to the underground retaining walls and
provide the strength against horizontal forces acting on the building ( wind and earthquake
forces) and also giving support to the upper floors structure. Inner to this concrete walls a
steel construction solution was chosen using a steel framed structure with composite steel
and light weight concrete slabs as the more suitable for future modifications of the floor
layout by adding or removing slab panels (see figure 3).
2.2 The Canopy
From two opposite mat foundations over concrete piles and connected by struts grows a
structure composed by reinforced concrete fins and shear walls, on top of which lay two
anchorage reinforced concrete slabs whose closer borders are 67.5 meters distant.
Figure 4 - Cross Section of the Canopy Structure
The canopy structure is a 20 centimetre thick parabolic membrane slab measuring in plan
approximately 65 meter by 50 meter and hanging from steel cables anchored along the two
short sides into anchorage slabs. The steel cables are unbounded and have an aerial
trajectory on each side of the canopy (see figure 5), releasing the canopy from the supporting
structure enabling a perfect control of its behaviour and isolating the canopy from induced
earthquake vibrations.
The small sag ( 3 meters against the 67.5 meters distance of supports) will induce large
horizontal thrust on the top of the fins. The use of light weight concrete provided a good way
to reduce that horizontal forces at the same time being adequate to provide the appropriate
strength and stiffness to assure the convenient distribution of thrust forces. That was
important to guaranty the 30 centimetres longitudinal slope for rain-water run-off, being
known that if it acted as in independent strips, one error of 1% in the cable force would cause
a deviation 10% of the longitudinal slope. Special study of the light weight concrete was
made to obtain the adequate strength and to achieve the construction of the membrane in
one only pour of concrete to avoid visible construction joints
Figure 5 - Detail of Canopy, Cables and Fins
Figure 6 - General View of Canopy
The small sag ( 3 meters against the 67.5 meters distance of supports) will induce large
horizontal thrust on the top of the fins. The use of light weight concrete provided a good way
to reduce that horizontal forces at the same time being adequate to provide the appropriate
strength and stiffness to assure the convenient distribution of thrust forces. That was
important to guaranty the 30 centimetres longitudinal slope for rain-water run-off, being
known that if it acted as in independent strips, one error of 1% in the cable force would cause
a deviation 10% of the longitudinal slope. Special study of the light weight concrete was
made to obtain the adequate strength and to achieve the construction of the membrane in
one only pour of concrete to avoid visible construction joints
3. THE USE OF LIGHT WEIGHT CONCRETE
To reduce the dead weight of the structure a special concrete was studied, with a mass
density lower than 1800 kg/m3, concrete that must reach a minimum strength LC25 and
being to be pumped at distances up to 60 meters.
The formula for this concrete used:
•
•
•
•
•
•
Portland Cement Type Ι 42.5
Flying Ashes (from Sines Power Plant)
Silica Fumes (MS 610 from MBT)
Natural Sand (Siliceous)
Expanded Clay (LECA 2-4)
Superplastifier (Rheobuilh 561)
Figure 7 - Scheme for Pouring Concrete for Canopy
Special concern was taken with the absorption of water by expanded clay and the
consequent modifications of the concrete properties. Several tests were made to obtain the
best results.
Preliminary tests showed that even the diameter of the pump ducts could affect the results by
the warming of the concrete as a consequence of friction against the wall of the ducts.
Figure 8 - Pouring Concrete
The operations of pouring the concrete over the more than 3900 sq. m of falsework started
with a central strip 2.5 meters wide and continued with the help of 4 concrete pumps with a
production of 80 cu. m per hour according to the scheme shown in Fig. 7. The average delay
at working joints was no more than 45 minutes in order to get a full continuity in the bottom
surface of the concrete.
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