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International Journal of Civil Engineering and Technology (IJCIET)
Volume 9, Issue 9, September 2018, pp. 881–893, Article ID: IJCIET_09_09_084
Available online at http://www.iaeme.com/ijciet/issues.asp?JType=IJCIET&VType=9&IType=9
ISSN Print: 0976-6308 and ISSN Online: 0976-6316
©IAEME Publication Scopus Indexed
DESIGN OF MULTI-STOREY BUILDINGS TO
MITIGATE LOW TEMPERATURES AND
EARTHQUAKE HAZARD
Olga Markogiannaki
Aristotle University of Thessaloniki
Department of Civil Engineering
Konstantinos Psarras
Aristotle University of Thessaloniki
Department of Civil Engineering
Ioannis Tegos
Aristotle University of Thessaloniki
Department of Civil Engineering
Emeritus Professor
ABSTRACT
Expansion joints are often used in buildings to divide large floor plans to statically
independent structures. This practice is used to lower the effect of contraction due to
temperature and creep and shrinkage phenomena. When seismic hazard is considered
the required joint widths in buildings become even larger which results in high
construction and maintenance costs. In the last years, the perspective on the
phenomena that induce restraints and the quantitative tools to calculate them have
changed and there have been several research efforts on the development of jointless
structures. It has been observed that stiffness of vertical structural members plays a
key role in the response of buildings under temperature constraints. In contrast to the
beneficial effect on the seismic response, large stiffness of vertical structural members
increases the intensity of temperature effects. Therefore, it is important to develop
effective novel methods to control the stiffness of vertical members apart from
changing cross-section dimensions or ground floor height. The present paper focuses
on a novel method for “controlling” the stiffness of columns of multi-story structures.
A 15-storey building is used as a case study. The aim is to compromise the two
contradictory actions (seismic and thermal). 3D models of the building with and
without the proposed mechanism are developed and the analysis results are
compared. Based on the inter-story drift effects on jointless high–rise structures, it is
illustrated that even large floor plans can be treated with no joints. The results show
the improved response of the jointless structure under extreme temperatures and
effective performance when subjected to seismic hazard.
Design of Multi-Storey Buildings to Mitigate Low Temperatures and Earthquake Hazard
http://www.iaeme.com/IJCIET/index.asp 882 editor@iaeme.com
Key words: temperature; seismic response; reinforced concrete buildings; jointless
structure; stiffness control
Cite this Article: Olga Markogiannaki, Konstantinos Psarras, Ioannis Tegos, Design
of Multi-Storey Buildings to Mitigate Low Temperatures and Earthquake Hazard.
International Journal of Civil Engineering and Technology, 9(9), 2018, pp. 881-893.
http://www.iaeme.com/IJCIET/issues.asp?JType=IJCIET&VType=9&IType=9
1. INTRODUCTION
Current building design practice and regulations [1] suggest expansion joints to structures
with large floor plans, as means to avoid increased stresses due to imposed deformations in
the serviceability limit state including temperature and creep and shrinkage phenomena. The
vulnerable members of such buildings are the columns of the ground floor, as the differential
deformations between ground and first floor slab induce additional stresses on these columns.
Moreover, in seismic areas, requirements are further increased due to seismic hazard and the
finally required joint widths are significantly large (i.e. EC8 specifications). A reason for the
wide use of joints has been the idea that is more convenient to let the structures expand rather
than resist the increased demand produced by the imposed deformations (i.e. temperature,
shrinkage) in integral structures. The wide use of joints has also been based partly on the
difficulties of traditional design in analyzing large undetermined structures, as nonlinearities
have to be considered. Furthermore, the presence of joints allows the use of various
construction techniques, i.e. the efficient use of precast members. However, experience of
construction practice has shown that joints in structures arise even more issues than those they
accommodate. The presence of joints undermines durability of structures with problems such
as moisture and corrosion or additional deformations induced by faulty joints. There are also
aesthetic-design issues, since they need double supports at their ends. In addition, their cost
(construction and maintenance) is not negligible to that total lifetime cost of structures [2].
Therefore, joints can be uneconomical design solutions, especially, in seismic prone areas,
where seismic demand increases significantly joint widths due to large seismic relative
displacements.
These concerns have motivated a turn to the construction of jointless, also called integral,
structures to accommodate the problems that arise with the use of joints. Integral structures
have long lifetime without additional maintenance costs. The elimination of joints in
combination with efficient response against thermal and seismic actions can be considered as
a design solution. In the last years, the advancements in technology and in numerical analysis
for undetermined structures has led to successful construction of a large number of jointless
structures, i.e. Kaltern swimming center in Germany, that have reliable behavior against
design loads. Kumar and Vidhya [3] performed a numerical study on the effect of thermal
and seismic actions on a multistory jointless building that showed the significance of seasonal
thermal and seismic actions on buildings. There have also been other publications for jointless
or with limited joints structures [4,5] but they are mainly based on empirical experience.
A critical aspect considered in the design of jointless structures is the accommodation of
the restraints induced by temperature and creep and shrinkage. There have been some
research efforts regarding the response of structures under induced restraints. Hock [6] studied
the origins and size of the imposed deformations on structures showing the importance of
column capacity and deformability under large horizontal slab displacements, while
Wohlfahrt et al [7] tested columns under restrained deformations. Noakowski et al [8] studied
the relation of column stiffness and crack growth to shear forces developed in columns under
imposed restraints. Knowledge on crack growth mechanism [9] and nonlinear response of
reinforced concrete members [10] are necessary to understand the nature of these phenomena.
Olga Markogiannaki, Konstantinos Psarras, Ioannis Tegos
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Other researchers, like Caldentey et al [11] and Groli et al [12], have focused on experimental
and analytical investigations on the improvement of the design methods used for columns of
long jointless structures, which have been identified as critical structural members in terms of
serviceability requirements, concluding that current Codes are quite conservative considering
the limit lengths for jointless structures. However, these research studies lack any suggestions
to improve the response of columns subjected to temperature and other phenomena that
induce restraints and to eliminate the intermediate expansion joints.
In the light of the above, a method that contributes to the development of jointless
structures is presented herein. The authors have conducted a preliminary research on this
method in Markogiannaki et al. [13]. The target is to control column stiffness and increase
flexibility which is the dominant factor that affects stresses and deformations on columns by
the imposed temperature and seismic loading. Stiffness is controlled with a novel type of
cross-section for the outer corner columns which has the advantage of flexibility and consists
of a bundle of columns, symmetrically arranged, statically independent, circular cross-
sections in contact with each other. The cross-section has the characteristic of multiple
smaller cross sections replacing a larger solid one. A similar approach has been proposed by
Tegos and Pilitsis [14] for bridge piers to increase bridge flexibility without the use of any
isolation devices. The proposed method is applied in a 15-story building with 80mx20m
layout dimensions and the structural performance against extreme temperature and seismic
hazard is evaluated. The as-built building has small local joints and non-integral connections
between the outer columns and slabs at the ground floor level. Despite the fact that extensive
expansion joints through the building layout were avoided in this design, the solution of a
complete elimination of joints was not explored. The analysis results indicate the improved
structural safety of the fully integral building.
2. DESCRIPTION OF GROUND FLOOR COLUMN GROUP
The alternative column cross-section that is explored in the present paper aims to control
column stiffness and increase column flexibility. The ultimate goal is to eliminate the need of
joints and address both temperature and seismic demand. In typical building structural
systems, the ground floor columns and beams are the most vulnerable structural components
to serviceability (temperature, creep, shrinkage) deformations due to the varying response of
the top and bottom of columns at the ground floor level which results in high drift values at
this floor level. Furthermore, the demand on columns is higher as the column distance from
the center increases. Therefore, the proposed column design approach discussed herein is
applied at the corner columns of the ground floor. The proposed column approach includes
the following design aspects: Smaller circular cross-sections, equal in diameter, replace the
large solid cross section of the perimeter building columns. The schematic representation of
the proposed configuration is illustrated in Fig. 1. In this way the massive solid columns are
fragmentized and have increased flexibility to address deformations imposed by temperature,
creep and shrinkage. Although the system becomes more flexible, if key elements for seismic
response are used, like shear walls, the system behaves effectively against seismic hazard, as
well. The columns are replaced only in the ground floor, while in the upper floors the initial
column cross section is used. The continuity between the lower and upper floor columns is
achieved through the height of the concrete slab between them. Such buildings often have
slabs with large heights which provide adequate space for the appropriate anchorage of the
vertical column reinforcement.
Design of Multi-Storey Buildings to Mitigate Low Temperatures and Earthquake Hazard
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(a) (b)
Figure 1 Schematic plan of the group of columns for (a) rectangular solid cross section, (b) circular
column cross section
The proposed column type is easy to construct, as it is possible to use cardboard
disposable formworks that are widely available and of low cost in current construction
practice and aesthetics are also considered for the final column configuration.
Regarding the structural response of the smaller circular columns buckling issues are
considered. Therefore, a criterion is determined regarding the minimum column dimensions.
The criterion relates the Euler buckling load to the upper bound of the normalized axial force
due to ductility demand. In common building structures, the normalized axial load vd shall be
smaller or equal in absolute values to 0.65 [15]. Eq. (1) and (2) show the derivation of the
formula of the minimum critical diameter of each column cross section with respect to the
upper bound of the axial force.
2
2
2
2 2
2
2
H
0.65 0.65H ( / 4)
4
0.65 H
c ccr
cr c cd
c ck cr ck
c ccr
ck
Pk
Pv
A f k d f
dk f
(1)
(2)
Where, Ec is modulus of elasticity of column, IC column moment of inertia, H is the
column height and k factor depending on fixity conditions , Ac is the column cross section, fck
is the concrete strength, dcr is the column diameter. P-Delta effects are also considered in the
selection of the appropriate column cross sections and column reinforcement is calculated
from critical seismic and non-seismic load combinations.
3. MULTI-STOREY BENCHMARK BUILDING
The building used as the benchmark structure in the case study is a 15 – storey concrete
building with one basement and a plan layout of 79m*19.5m. It is a typical example of
buildings with long dimensions. It consists of a basement, a ground floor that is 4.5m high
and 14 typical floors that are 3.2m high. In Fig. 2 the structural layout of the typical floors is
illustrated. The building is plan symmetric in the Y-direction, while the staircase and elevators
break the symmetry in the X-direction.
According to common practice expansion joints are required for lengths beyond 30-35m.
In particular, in this building due to the presence of the concrete core in the middle a single
Olga Markogiannaki, Konstantinos Psarras, Ioannis Tegos
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joint is not feasible and two expansion joints are required. However, the building was studied
with a limited local joint solution at the column-slab connections to avoid the need of large
joint widths due to seismic demand and the need of double elements at joint locations.
There are circular columns with a diameter equal to 90cm around the perimeter, 4 shear
walls at the perimeter and a central core of shear walls. A characteristic of the system due to
operational needs is the absence of inner columns that result in span lengths equal to 18m and
the absence of beams. The concrete slab (Fig. 2(b)) has a total height of 60cm, is sandwich-
voided filled with polystyrene for lowering the self-weight of the slab and is prestressed due
to the increased demand for controlling deflection, tension stresses and to avoid cracking. The
tendons have parabolic geometry and consist of 5 strands. The foundation is a concrete slab of
1m height and prestressed as well. Further information on dimensions of the structural
elements and their reinforcement detailing can be found in Fig. 3(b-d). The concrete strength
is fck=35MPa and steel strength fyk=500MPa. The tendons are St1670/1860. The building is
located in a moderate seismic hazard region, seismic zone II – 0.24g, and soil class is B [15].
To address the temperature, creep and shrinkage deformations two strategies were
employed: a) the first strategy included the division of the cross – section of the outer
concrete shear walls at the ground floor level with polystyrene to 2 equal smaller cross
sections, as shown in Fig. 3 (a). The initial width of the shear wall is 50cm and is divided to
two 25cm wide cross sections. This separation results to smaller shear wall stiffness in the
critical (longitudinal) direction which lowers the resistance to deformations, as well, without
reducing the stiffness in the transverse direction, Fig. 4. b) the second strategy involved the
introduction of joints, 2cm wide, at the connections of the 4 corner columns of the ground
floor with the 1st floor slab and the extension of the column to slab support with a height of
40cm, as shown in Fig. 3(b).. As the serviceability demand is smaller in the middle of the
structure, the width of local joints is reduced from the corner to the middle accordingly. These
column to slab joints are located at all column positions that exceed 15m distance from the
middle at both sides of the building. The local joints are introduced to avoid the development
of cracking in the slabs. Regarding the seismic response of the building in the benchmark
solution, it should be taken into account that since the introduced joints for temperature and
creep and shrinkage have small width they will close very quickly under seismic excitation.
After the closure of the gap, the columns will be activated and will contribute to the seismic
resistance of the building along with the concrete core and the shear walls. In the present
study, the change of the column stiffness with a group of columns with smaller cross-section
is an attempt to develop a fully integral structure with the elimination of all types (local or
extended) of joints that hasn’t been achieved for the building under study.
(a)
Design of Multi-Storey Buildings to Mitigate Low Temperatures and Earthquake Hazard
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(b) (c)
(d)
(e)
Figure 2 (a) typical floor plan, (b) concrete slab detail, (c) typical column detail, (d) concrete core
(upper part) detail, (e) foundation slab
(a)
Olga Markogiannaki, Konstantinos Psarras, Ioannis Tegos
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(b)
Figure 3 (a) Ground floor corner concrete shear walls (b) Column-Slab joint detail
Figure 4 Location of local joints
4. 3D BUILDING MODELS
For both solutions 3D non-linear models were developed in SAP2000 [16]. The finite element
model of the benchmark building is shown in Fig. 5(a). The columns are modeled as frame
elements with concentrated plasticity. The moment-curvature curves were derived from cross-
section analysis in the free software Any Section [17] based on the dimensions and
reinforcement of the circular solid columns. The concrete shear walls and cores are modeled
with frame elements. Rigid elements are introduced at the top and bottom of the shear walls at
each floor. The floor slab was modeled with equivalent I-shaped beams, beff=1,2m, h=0.6m,
and shell elements in the perimetric full-concrete zones. The tendons were modeled with
tendon elements with the respective dimensions, geometry and values for losses according to
Eurocode 2[1]. The foundation slab was modeled accordingly, with equivalent I-shaped
beams, beff=6m, and shell elements in the perimetric full-concrete zones and the basement
concrete shear walls. The soil was modeled with equivalent linear springs with
ks=20000kN/m. P-Delta effects are taken into account in the analysis. The mass of each floor
is calculated based on the values of the permanent and part of the live loads. The total values
for the characteristic floors are presented in Table 1.
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Figure 5 (a) finite element model, (b) frame elements, (c) shell elements
The finite element model of the group of columns (modified) solution has the same
properties with the finite element model of the benchmark building. It only has different
column configuration at the four corners of the building at the ground floor, as shown in
Fig.6, which results in a more flexible system with smaller column stiffness. After a crack
development analysis according to [18] and from Eq. 2, the critical (minimum) column
diameter is derived, dcr=0.30m. It is found that such a diameter can accommodate up to 5cm
of column displacement. Longitudinal reinforcement ratio for the small 30cm diameter
columns is assumed the minimum, ρl=1%, which is verified for all critical load combinations
according to Eurocode 8 [19]. In Fig. 6, the column characteristics and the respective
modeling are presented.
Figure 6 Modified building 3D Model
Table 1 Mass distribution
Floor m(tn)
Roof 2312.33
Typical Floor 2276.40
Ground Floor 2355.91
The input ground motions used for seismic analysis are seven ground acceleration records
matching EC8 spectrum derived from Rexel [20], Fig. 7.
Olga Markogiannaki, Konstantinos Psarras, Ioannis Tegos
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Figure 7 Accelerograms matching code spectrum for seismic zone II
5. ANALYSES AND DISCUSSION OF RESULTS
Comparative analysis was conducted for the two structures, the benchmark building and the
modified- fully integral with the group of columns with smaller cross section. The analyses
included static analysis for temperature deformations and dynamic analysis for the seismic
demand. The target of the analysis was to verify that the imposed deformations are acceptable
in the modified case where joints are avoided and that seismic forces are efficiently received.
Firstly, the response of the benchmark building was investigated against temperature
loading. Regarding seasonal temperature effects, current regulations (i.e. CEN [Comité
Européen de Normalisation] 2003) determine extreme low and high values that are
considered in the design. Low values cause contraction, while higher cause expansion of the
floor slabs. Due to the presence of creep and shrinkage thermal actions that cause expansion
are counterbalanced and are not critical in the analysis. On the contrary, lower temperatures
cause further contraction and their effect is crucial for the investigation of the fully integral
building response. The extreme temperature value considered in the analysis is -25 o
C. An
additional -25oC temperature (Rhodes and Carreira 1997) is used as a simplification to
account for creep and shrinkage. Therefore, equivalent temperature of -50oC was applied to
account for thermal contraction due to extremely low temperatures, creep and shrinkage. The
deformed shape of the benchmark building is shown in a three dimensional view in Fig. 8a.
As shown in Fig. 8b and 8c, the deformations are larger at the corner columns when compared
to the middle of the structure. Furthermore, it is evident that large drift values are developed
only in the ground floor columns due to the varying response of the foundation and the 1st
floor. In the upper floors drift is very small, since both at their top and bottom the same
restraints are induced. It is observed that the temperature analysis results are in accordance
with the application of the proposed system at the ground floor of the building.
The temperature effects are also investigated for the modified-fully integral structural
system with the smaller column cross sections and smaller column stiffness. In Fig. 9, the
comparative drift results for both structures (benchmark and modified) are illustrated. For the
benchmark building, maximum drift value at the corner column is smaller than the width of
the joints at the column to slab connections (1.7cm) which shows that the limited joint
selection is efficient for thermal actions. In the modified structural system, contraction due to
temperature induces cracking due to the integral (monolithic) column to slab connection.
Based on the diagrams provided in Tegos, Giannakas, and Chrysanidis (2011) crack growth is
Design of Multi-Storey Buildings to Mitigate Low Temperatures and Earthquake Hazard
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calculated and crack widths are found lower than 0.2mm which are acceptable according to
the allowable cracking level provided by EC2 [1].
(a)
(b)
(c)
Figure 8 Deformed Shape benchmark structure a) 3D view, b) plan view, c) elevation view
Olga Markogiannaki, Konstantinos Psarras, Ioannis Tegos
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Figure 9 Drift in longitudinal x direction due to temperature effects
The two buildings were also investigated for their response when subjected to seismic
hazard. It is noted that the aim of the analysis under is to verify that the proposed method has
efficient seismic response. The investigation is driven by the concept that temperature
restraints and seismicity are contradictory and often interventions that are beneficial for the
one have negative effects on the other.
In Fig. 10, the seismic drift for each floor for the benchmark and the modified building are
illustrated and compared to drift limits provided by Eurocode 8 - Part1 [15]. The modified
building has smaller column stiffness, therefore it is more flexible. Although there are slightly
larger drifts in the modified building, the resulting values are far lower than the failure
threshold. The modified system affects slightly the response since the core and the shear walls
contribute the most to the building seismic resistance. This is evident in Fig. 11 where the
seismic base shear for the longitudinal and transverse earthquake direction is presented. Base
shear is divided into two categories; shear wall-core, column and it is observed that the
contribution of the shear walls and concrete core in receiving seismic forces is much higher
than that of the columns.
(a) (b)
Figure 10 Seismic Drift for seismic zone II (a) x direction (b) y direction
Design of Multi-Storey Buildings to Mitigate Low Temperatures and Earthquake Hazard
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(a) (b)
Figure 11 Base seismic shear ratio for vertical structural components
6. CONCLUSIONS
The present paper focuses on an alternative column configuration for buildings with long
layouts to avoid the use of expansion joints. Smaller circular cross-sections, equal in diameter,
replace the large solid cross section of the perimeter building columns at the ground floor
level. The presented group of columns has smaller stiffness than the initial solid one resulting
in higher flexibility. Analyses were conducted in a 15 storey reinforced concrete building to
evaluate the structural response against temperature and earthquake hazard. The following
conclusions are derived from the analysis results for the benchmark and the modified system
without expansion joints:
The fully integral structure avoids the introduction of joints, even the limited joints provided
in the studied building case. This elimination of joints addresses issues, like high construction
and maintenance costs.
The study for the imposed restraints due to temperature and creep and shrinkage has shown
that they are accommodated in the modified building case. The top ground floor displacements
are lower than the limit values for cracking development
Although the modified system is more flexible and could affect the seismic response, it is
observed in the analyses results that the modified system’s seismic response is very close to
the benchmark building’s response which is attributed to the fact that the concrete shear walls
and not the columns have the major contribution to the seismic resistance. For both
benchmark and modified systems the seismic drift values are below EC8 limits.
Regarding the aesthetic aspect of the presented solution in the modified system, according to
the authors’ opinion, aesthetics is not harmed and, the column configuration can be used as an
architectural feature of the building.
ACKNOWLEDGMENTS
The authors wish to express their gratitude to METE SYSM S.A. for providing the original
study of the building for the purposes of the present paper.
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