Jtam-A4.dvi


JOURNAL OF THEORETICAL

AND APPLIED MECHANICS

51, 4, pp. 891-902, Warsaw 2013

GLOBAL BUCKLING PREVENTION CONDITION OF ALL-STEEL

BUCKLING RESTRAINED BRACES

Nader Hoveidae, Behzad Rafezy

Sahand University of Technology, Faculty of Civil Engineering, Sahand, Tabriz, Iran

e-mail: hoveidae@gmail.com; nader.hoveidae@polymtl.ca; rafezyb@sut.ac.ir

One of the key requirements for the desirable mechanical behavior of buckling restrained
braces (BRBs) under severe lateral loading is to prevent overall buckling until the brace
member reaches sufficient plastic deformation and ductility. This paper presents finite ele-
ment analysis results of proposed all-steel buckling restrained braces. The proposed BRBs
have identical core sections but different Buckling Restraining Mechanisms (BRMs). The
objective of the analyses is to conduct a parametric study of BRBs with different amounts
of gaps and cores and BRM contact friction coefficients to investigate the global buckling
behavior of the brace. The results of the analyses showed that BRMflexural stiffness could
significantly affect the global buckling behavior of a BRB. However, the global buckling
response occurred to be strongly dependent upon the magnitude of the friction coefficient
between the core and the encasing contact surfaces. In addition, the results showed that the
global buckling response of BRBswith direct contact of the core andBRM ismore sensitive
to the magnitude of contact friction coefficient.

Key words: all-steel buckling restrained brace, global buckling, finite element analysis,
contact friction coefficient, cyclic loading

1. Introduction

Seismic excitations have led to concerns in structural design in earthquake-prone zones. During
severe ground motion, large amount of kinetic energy is transmitted into a structure. Seismic
codes and studies have been recognized that it is not economical to dissipate the seismic ener-
gy within the elastic capacity of materials and, as a consequence, it is preferable to anticipate
yielding in some controlled elements. Braces are preliminary devices for energy absorption in
braced buildings. However, buckling of the brace in compression results in sudden loss of stif-
fness, strength, and energy dissipation capacity. To overcome this deficiency, various types of
innovations have beenproposed in steel braces inwhich the buckling has been inhabited through
amechanism.

Buckling Restrained Braced Frames (BRBFs) have been widely used in recent years. A
BRBF differs from a conventionally braced frame because it yields under both tension and
compression without significant degradation in compressive capacity. Most buckling restrained
brace (BRB) members currently available are built by inserting a steel plate into a steel tube
filled with mortar or concrete called conventional BRBs. The steel plate is restrained laterally
by the mortar or the steel tube and can yield in compression as well as tension, which results
in comparable yield resistance and ductility as well as a stable hysteretic behavior in BRBs. A
large body of knowledge exists on conventional BRBs performance in the literature. Black et al.
(2002) performed component testing of BRBs and modeled a hysteretic curve to compare the
test results, and found that the hysteretic curve of a BRB is stable, symmetrical, and ample.
Inoue et al.(2001) introduced buckling restrained braces as hysteretic dampers to enhance the
seismic response of building structures. As shown in Fig. 1, a typical BRB member consists



892 N. Hoveidae, B. Rafezy

of a steel core, a buckling restraining mechanism (BRM), and a separation gap or unbonding
agent allowing independent axial deformation of the inner core relative to the BRM. Numerous
researchers have conducted experiments and numerical analyses on BRBs for incorporation
into seismic force resisting systems. Qiang (2005) investigated the use of BRBs for practical
applications for buildings in Asia. Clark et al. (1999) suggested a design procedure for buildings
incorporating BRBs. Sabelli et al. (2003) reported seismic demands on BRBs through a seismic
response analysis of BRB frames, and Fahnestock et al. (2007) conducted a numerical analysis
and pseudo dynamic experiments of large-scale BRB frames in the U.S.

Fig. 1. Components of a BRB

The local buckling behavior of BRBs was studied by Takeuchi et al. (2005). The effective
buckling load of BRBs considering the stiffness of the end connection was recently studied
by Tembata et al. (2004) and Kinoshita et al.(2007). Previous studies have demonstrated the
potential ofmanufacturingBRB systemsmade entirely of steel, called all-steel BRBs (Tremblay
et al., 2006). In a conventional all-steel BRB, the steel inner core is sandwiched with a buckling
restrainingmechanismmade entirely of steel components, thus avoiding the costs of themortar
needed in conventional BRBs. This eliminates the fabrication steps associated with pouring
and curing the mortar or concrete, significantly reducing manufacturing time and costs. In
addition, suchaBRBcanbeeasilydisassembled for inspectionafteranearthquake.Experimental
and analytical studies on the deformation performance and dynamic response of BRBs were
performed by Kato et al. (2002), Watanabe et al. (2003), and Usami (2006). The restraining
member proposed previously was a mortar-filled steel section, which made an extremely rigid
member. In such types of BRBs, the brace member and the BRM were integrated, and overall
buckling did not occur. However, in all-steel BRBs, which are considered to be a new generation
of buckling restrained braces, the brace system ismade completely of steel, and theBRMsystem
is lighter in comparisonwith conventional BRBs,which leads to a highpotential for brace overall
buckling caused by the low rigidity and stiffness of theBRM.The hysteretic behavior of all-steel
BRBswas experimentally investigated byTremblay et al. (2006). An experimental study on the
hysteretic response of all-steel BRBs was also conducted by Eryasar and Topkaya (2010).

The following characteristics are considered necessary for the safe performance of BRBs:
1) the prevention of overall buckling, 2) the prevention of core local buckling, 3) the prevention
of low cycle fatigue of the bracemember, and 4) high strength of the joint parts and connections.
In this paper, the first characteristic (i.e., overall buckling behavior) is examined further.

Assume a BRB member with initial deflection under compression. When the inner core
with initial inherent imperfection deflects under compression, it comes into contact with the
BRM. The contact forces increase the out-of-plane deformation of the entire BRB and strength
deterioration occurs before the bracemember reaches the target displacement if the rigidity and
strength of theBRMare insufficient.According to theAISC2005 guidelines for qualifying cyclic
tests of BRBs (AISC 2005), a BRB should undergo axial deformations up to ∆bm, where ∆bm
is the brace axial deformation corresponding to the design story drift. The buckling restraining
component should have enough strength and rigidity to prevent overall buckling of the brace
during axial deformation. Therefore, to obtain the hysteretic characteristic on the compression
side similar to that on the tension side and to mitigate pinching, it becomes necessary to avoid



Global buckling prevention condition of all-steel ... 893

overall buckling (i.e., flexural buckling). The results of the first studies on overall buckling
behavior of BRBs conducted by Watanabe et al. revealed that the ratio of Euler buckling load
of the restraining member to the yield strength of the core, Pe/Py, is the factor that is the
most determinative for control of brace global buckling(Watanabe et al., 1988). These authors
concluded that if the ratio of the Euler buckling load of the BRM to the yield load of the
inner core, Pe/Py, is less than one, the brace member will experience overall buckling during
cyclic loading of the braced frame. However, a Pe/Py ratio of 1.5 was proposed for design
purposes in the studiesmentioned. The criterion Pe/Py ­ 1 has a theoretical basis (Black et al.,
2002) and has been verified through experimental testing (Iwata and Murai, 2006). However,
the aforementioned studies did not consider the contact properties between the core and the
encasing. In other words, the friction coefficient of the core and the encasing contact surface
was not considered as an affecting parameter thatmight change the overall buckling prevention
condition of a BRB. More experimental studies were conducted by Usami (2006) on all-steel
BRBs and a safety factor of λf = Pmax/Py was proposed where Pmax and Py denote the
maximum compression force in the brace member and the core yielding capacity, respectively.
The safety factor is illustrated as follows

γf =
1

Py
Pe
+
Py
My
(a+d+e)

(1.1)

where a, d and e are the initial deflection, gap amplitude, and the eccentricity of loading,
respectively. Test results showed that if the value of safety factor γf was greater than three,
overall buckling of BRBwould not occur.

The finite element analysis method was recently used with success to predict the buckling
response of the core plates in BRBmembers with tubes filled withmortar (Matsui et al., 2008).
Subsequent finite element analysis studies have been conducted by Korzekwa and Tremblay
(2009) to investigate the core buckling behavior in all-steel BRBs. The studiesmentioned above
also provided a description of the complex interaction that develops between the brace core
and BRM. Outward forces induced by the contact forces were found to be resisted in flexure
by the BRM components and in the bolts holding together the BRM components located on
each side of the core. In addition, the contact forces resulted in longitudinal frictional forces
that induced axial compression loads in theBRM.The representative Pe/Py ratio used in these
studies was 3.5, and the test results showed that the encasing strength was adequate to prevent
global buckling of the brace.

Thispapernumerically investigates theoverall buckling inhibition condition of all-steelBRBs
regarding the effect of gap size and the friction coefficientmagnitude of the contact between the
core and the buckling restraining mechanism.

2. Overall buckling prevention criterion of BRBs

Analysis of elastic buckling of a BRB composed of a steel core restrained laterally by a BRM
showed that the Euler buckling load of the bracemember under compression could be found by
solving an equilibrium equation as follows (Fujimoto et al., 1988)

EBIB
d2v

dx2
+(v+v0)Nmax =0 (2.1)

in which EBIB is the flexural stiffness of the BRM, Nmax represents the maximum brace
axial load, and v and v0 denote the transverse and the initial deflection of the brace member,
respectively, as shown in Fig. 2.



894 N. Hoveidae, B. Rafezy

Fig. 2. Force and deformation of a BRB (Qiang, 2005)

The initial deflection of the brace is assumed to be expressed by a sinusoidal curve as follows

v0 = asin
πx

L
(2.2)

where a is the initial deflection of the brace at the center and N is the brace axial load, which is
replacedwith P in the following equations. Solving equilibriumEq. (2.1) results in the following

v+v0 =
a

1− Pmax
Pe

sin
πx

L
(2.3)

The bendingmoment at the center of BRM can be written as follows

Mc =
Pmaxa

1− Pmax
Pe

(2.4)

where Pmax is the maximum axial force of the brace. Assuming that Pmax is equal to Py (i.e.,
yield load of the core) and considering that the buckling of the BRB occurs when themaximum
stress in the outermost fiber of the BRM reaches the yield stress, the requirement for stiffness
and strength of the steel tube (BRM) can be obtained as follows

Pe
Py
­ 1+

π2EBaD

2σyL
2
B

(2.5)

in which LB, σy, and D denote the length, the yield stress of the steel tube, and the depth of
the restrainingmember section, respectively. This is the first formula that successfully expresses
strength and stiffness requirements as paired in the design of BRBs. In this formula, the effect
of gap amplitude g has not been considered in the calculation of the moment at the center of
the BRM (Qiang 2005). Therefore, in this paper, this parameter is involved in Eq. (2.5). Thus,
Eq. (2.5) can bemodified as follows

Pe
Py
­ 1+

π2EB(a+g)D

2σyL
2
B

=β (2.6)

where LB is the length of the core and BRM (equal together), and D s the depth of the BRM
section. Equation (2.6) indicates that overall buckling of the brace will not occur if the ratio
Pe/Py is greater than the parameter β, which is calculated based on the geometric andmaterial
characteristics of the brace member.

3. Finite element analysis

To provide a numerical understanding of the cyclic behavior and buckling response of all-steel
BRBs, a series of finite element analyses were conducted on 24 proposed all-steel BRBs. A
three-dimensional representation of the brace specimens was developed to properly capture the
expected behavior. The models included the core plates, and the BRM components consist of
tubes, guide plates, filler plates, and end stiffeners.



Global buckling prevention condition of all-steel ... 895

3.1. Description of the models

Finite element analyses have been conducted on 24 proposed all-steel BRBs. Table 1 repre-
sents the details and specifications of the models where the second column shows the specimen
code in the form S(i)g(j)c(k), in which the indexes i, j, and k represent the model number,
the gap amplitude, and the friction coefficient magnitude at the interface, respectively. All of
the models consisted of a constant 100mm×10mm core plate with various cross sections for
BRMmembers, as shown inTable 1. Therefore, the yield strength of the core was kept constant
when the stiffness and strength of the BRMs were altered. The total length of the BRBs, L,
was assumed to be 2000mm. The core plate yield load, Pyc, which is illustrated by Py, was
calculated by multiplying the yield stress by the cross-sectional area, and the buckling load of
theBRM, Pe, was calculated from theEuler buckling load formula. The dimensions of the brace
components were selected in a way that the ratio of the Euler buckling load and the yield load
of the brace in the specimens, Pe/Py, falls between 1.09 and 2.60. The parameter Ir in Table 1
denotes the moment of inertia of the restraining member.

Table 1.Properties of BRB specimens

No.
Model BRM section Core dimen- Ac Gap Ir Pe Pyc
name dimensions [mm] sions [mm] [mm2] [mm] [mm4] [KN] [KN]

1 S1g0c0.1 UNP50+2Fp(45×5) P-100×10 1000 0 81.46E+4 401.99 370

2 S2g0c0.1 UNP65+2Fp(37.5×5) P-100×10 1000 0 111.84E+4 551.91 370

3 S3g0c0.1 B(50×50×3)+2Fp(45×5) P-100×10 1000 0 148.46E+4 732.62 370

4 S4g0c0.1 B(50×50×4)+2Fp(45×5) P-100×10 1000 0 190.00E+4 937.61 370

5 S1g0c0.3 UNP50+2Fp(45×5) P-100×10 1000 0 81.46E+4 401.99 370

6 S2g0c0.3 UNP65+2Fp(37.5×5) P-100×10 1000 0 111.84E+4 551.91 370

7 S3g0c0.3 B(50×50×3)+2Fp(45×5) P-100×10 1000 0 148.46E+4 732.62 370

8 S4g0c0.3 B(50×50×4)+2Fp(45×5) P-100×10 1000 0 190.00E+4 937.61 370

9 S1g0c0.5 UNP50+2Fp(45×5) P-100×10 1000 0 81.46E+4 401.99 370

10 S2g0c0.5 UNP65+2Fp(37.5×5) P-100×10 1000 0 111.84E+4 551.91 370

11 S3g0c0.5 B(50×50×3)+2Fp(45×5) P-100×10 1000 0 148.46E+4 732.62 370

12 S4g0c0.5 B(50×50×4)+2Fp(45×5) P-100×10 1000 0 190.00E+4 937.61 370

13 S1g1c0.1 UNP50+2Fp(45×5) P-100×10 1000 1 85.00E+4 419.46 370

14 S2g1c0.1 UNP65+2Fp(37.5×5) P-100×10 1000 1 116.00E+4 572.44 370

15 S3g1c0.1 B(50×50×3)+2Fp(45×5) P-100×10 1000 1 152.60E+4 753.05 370

16 S4g1c0.1 B(50×50×4)+2Fp(45×5) P-100×10 1000 1 195.23E+4 963.42 370

17 S1g1c0.3 UNP50+2Fp(45×5) P-100×10 1000 1 85.00E+4 419.46 370

18 S2g1c0.3 UNP65+2Fp(37.5×5) P-100×10 1000 1 116.00E+4 572.44 370

19 S3g1c0.3 B(50×50×3)+2Fp(45×5) P-100×10 1000 1 152.60E+4 753.05 370

20 S4g1c0.3 B(50×50×4)+2Fp(45×5) P-100×10 1000 1 195.23E+4 963.42 370

21 S1g1c0.5 UNP50+2Fp(45×5) P-100×10 1000 1 85.00E+4 419.46 370

22 S2g1c0.5 UNP65+2Fp(37.5×5) P-100×10 1000 1 116.00E+4 572.44 370

23 S3g1c0.5 B(50×50×3)+2Fp(45×5) P-100×10 1000 1 152.60E+4 753.05 370

24 S4g1c0.5 B(50×50×4)+2Fp(45×5) P-100×10 1000 1 195.23E+4 963.42 370

B – BOX; Fp – Face plate; P – Plate

The core plate and BRM was modeled using 8-node C3D8 brick elements. Large displace-
ment static cyclic analysis was performedusing theABAQUS6.9.3 (2005) general-purpose finite
element program.The core plate was expected to undergo large plastic deformations and higher
mode buckling with pronounced curvature. Therefore, a refinedmeshwas adopted with five ele-
ments across theplate and twoover the thickness.A coarsermeshwasused for theBRMbecause



896 N. Hoveidae, B. Rafezy

most of this component was expected to remain elastic. Contact properties with hard stiffness
in the transverse direction and tangential coulomb frictional behavior were assumed between
the core and the BRM. Regarding studies in the field (Chou and Chen, 2010), a coefficient of
friction of 0.1 was adopted to provide a greasy interface between the core and the BRM in the
models. In addition friction coefficients of 0.3 (Korzekwa andTremblay, 2009) and 0.5 were also
adopted to provide a smooth and rough steel-to-steel contact surfaces between the core and the
encasing, respectively. The contact model allowed for the separation of the core plate from the
BRM element, which enabled the higher mode buckling of the core plate.

The core plate and the BRM components were made of steel with a yield stress of Fy =
370MPa. Young’s modulus of 200GPa and Poisson’s ratio of 0.3 were assumed for the core
plate and the BRM components. A nonlinear combined isotropic-kinematic hardening rule was
employed to reproduce the inelastic material property and, therefore, accurate cyclic behavior.
The initial kinematichardeningmodulus C and the rate factor γwereassumedtobe 8KN/mm2

and75, respectively (KorzekwaandTremblay, 2009).For isotropichardening,amaximumchange
in yield stress of Q

∞
=110MPaanda rate factor of b=4were adopted.An initial imperfection

of 2mm (i.e., L/1000) was considered in both the core plate and the BRM. Two types of
interfaces between the coreplate andBRMwere considered in themodels. In thefirst case, direct
contact of the coreplatewith theBRMwas implemented, and in the second case, gap amplitudes
of 1mm were provided through the core thickness. In addition, a constant gap amplitude of
2mm was provided through the core width (on both sides) in all models. Such a gap was used
to accommodate the free expansion of the inner core under axial loads. The axial deformation
was blocked at one end of bracing with a pinned connection. Axial displacements were imposed
at the other end following the cyclic quasi static protocol suggested by AISC seismic provisions
for BRBs (2005) as follows: 2 cycles at ±∆y, 2 cycles at ±0.5∆bm, 2 cycles at ±∆bm, 2 cycles
at ±1.5∆bm, and 2 cycles at ±2∆bm, where ∆y is the displacement that corresponds to the
yielding of the core, and ∆bm is the axial deformation of the brace corresponding to the design
story drift. Based on the previous studies by Tremblay et al. (2006), the peak strain amplitude
in full-length core braces typically falls in the range of 0.01 to 0.02 for common structural
applications, and the peak deformation in themajority of past test programs have been limited
to that range (Watanabe et al., 1988). In this study, ∆bmwas set to 20mm,which corresponds to
theaxial strainof 1% in thecore, andthecoreyieldingdisplacement ∆y was calculated as3.7mm
based on thematerial characteristics. Therefore, the ultimate axial displacement demand of the
brace during cyclic loading will be 2∆bm = 40mm, which corresponds to a core strain of 2%.
Therefore, the adopted value for the peak strain demand of the inner core seems reasonable.
A typical cross section of the proposed BRB member and its finite element representation are
shown in Figs. 3 and 4, respectively.

Fig. 3. Typical cross section of proposed BRBs



Global buckling prevention condition of all-steel ... 897

Fig. 4. Finite elementmodel of a proposed BRB

4. Results and discussions

Hysteretic responses in all of the BRBmodels are well predicted by the finite element model in
both elastic and nonlinear ranges. Figuree 5 and 6 illustrate the normalized hysteretic responses
of the braces. In the curves, compression is positive.

Fig. 5. Hysteretic responses of the proposed BRBs including direct contact of the core and BRM



898 N. Hoveidae, B. Rafezy

Fig. 6. Hysteretic responses of the proposed BRBs including a gap between the core and BRM

Axial force-displacement curves of the BRB models are captured from a point at the brace
end. This point is located in a region that essentially remains elastic because stiffener plates are
provided to prevent local buckling in the brace end. Therefore, the captured force-displacement
relation may not be a representation of the true stress distribution of the core during cyclic
loading, although the curves properly describe the deterioration in strength caused by the global
or local buckling of the brace. The axial force-deformation curves shown inFigs. 5 and 6 indicate
the sudden deterioration in the strength and overall buckling only in the models S1g0c0.1 and
S1g1c0.1 with lower values of Pe/Py among themodels with the friction coefficient of 0.1 at the
interface, whereas, in all of the othermodels with friction coefficient of 0.1, the stable hysteretic
responsewithout a significant change in the brace load carrying capacity is specified. In addition,
in the similar models with the friction coefficients of 0.3 and 0.5, a premature overall buckling
is observed which can be deducted from the hysteretic curves in Figs. 5 and 6. All of themodels
including direct contact with the friction coefficients of 0.3 and 0.5 experience global buckling
during a cyclic loading up to 2∆bm as shown in Figs. 5 and 6. In addition, all of the models
with the friction coefficient of 0.3 and 0.5 and containing a gap size of 1mm through the core
thickness experience overall buckling except models S4g1c0.3 and S4g1c0.5 with larger strength
and stiffness of BRM. The buckled shape of the brace is represented in Fig. 7a. The values of



Global buckling prevention condition of all-steel ... 899

Pe/Py have been calculated for all 24 BRB specimens and are given in Table 2. In addition, the
representative parameter β is calculated and shown in Table 2.

Fig. 7. (a) Overall buckling of model S1g0c0.1; (b) comparison of frictional dissipated energy in model
S4g1c0.1, S4g1c0.3, and S4g0c0.1

Table 2.Analytical results for the proposed BRBs

No.
Model

α= Pe
Py

β Global
name [8] buckling

1 S1g0c0.1 1.09 1.11 Yes

2 S2g0c0.1 1.49 1.13 No

3 S3g0c0.1 1.98 1.15 No

4 S4g0c0.1 2.53 1.15 No

5 S1g0c0.3 1.09 1.11 Yes

6 S2g0c0.3 1.49 1.13 Yes

7 S3g0c0.3 1.98 1.15 Yes

8 S4g0c0.3 2.53 1.15 Yes

9 S1g0c0.5 1.09 1.11 Yes

10 S2g0c0.5 1.49 1.13 Yes

11 S3g0c0.5 1.98 1.15 Yes

12 S4g0c0.5 2.53 1.15 Yes

13 S1g1c0.1 1.13 1.24 Yes

14 S2g1c0.1 1.55 1.26 No

15 S3g1c0.1 2.04 1.30 No

16 S4g1c0.1 2.60 1.30 No

17 S1g1c0.3 1.13 1.24 Yes

18 S2g1c0.3 1.55 1.26 Yes

19 S3g1c0.3 2.04 1.30 Yes

20 S4g1c0.3 2.60 1.30 No

21 S1g1c0.5 1.13 1.24 Yes

22 S2g1c0.5 1.55 1.26 Yes

23 S3g1c0.5 2.04 1.30 Yes

24 S4g1c0.5 2.60 1.30 No

[8] – Fujimoto et al. (1988)

Based on the results of analysis and as shown in Table 2, models with a Pe/Py ratio greater
than 1.2 and the friction coefficient of 0.1 donot experience overall buckling during axial loading
up to a core strain of 2%. In addition, in these models, the Pe/Py ratio is greater than the
parameter β. Therefore, the analysis results confirm the validity of Eq. (2.6). Moreover, the
buckling prevention condition (i.e. Pe/Py ­ 1.2) is not dependent on the gap size between the
core and the encasing member in the models with the friction coefficient of 0.1. Table 2 shows



900 N. Hoveidae, B. Rafezy

that themodelswith higher friction coefficients, such as 0.3 or 0.5, and including adirect contact
of the core and theBRMexperience global buckling despite of owning a larger Pe/Py ratio such
as 2.53. In addition, the models with the friction coefficients of 0.3 and 0.5 and containing a
gap of 1mm at the interface endure overall buckling when the Pe/Py ratio is less than 2.6. The
reason is that, in themodels with higher friction coefficient, the slippage of the steel core inside
theBRMdoes not occur freely and the applied axial displacement causes the brace (with initial
imperfection) to deform laterally instead of free axial deformation.

In addition, a part of frictional forces developed at the interface is transmitted into the
BRM, which causes the lateral deflection of the brace because of P-∆ effects. Therefore, the
overall buckling behavior of theBRBmembers is dependent on the brace interface detail proper-
ties especially the magnitude of the friction coefficient. Frictional dissipated energy in models
S4g1c0.1, S4g1c0.3, and S4g0c0.1 is compared together in Fig. 7b. As shown in Fig. 7b, the
BRB with the direct contact of the core and BRM own larger frictional dissipated energy in
comparison to the BRB including the gap. In addition, the frictional dissipated energy in the
BRBmodel with the higher friction coefficient is larger.

During cyclic loading of aBRBmember containing a gap between the core and the encasing,
the brace member causes lateral deflection as the compressive displacement increases and the
lateral deflection rises.Contact forces acting on theupper side of theBRMincrease, andbuckling
of thebracemember occurswhen themoment at the center of theBRMas a result of the contact
forces reaches the yieldmoment of theBRM. Inmodels containing the gap, the lateral deflection
rises to deformation of higher order buckling modes while enforcing compression displacement.
The contact forces acting on both sides of the restraining member increase under compression
and cause global buckling of the brace. The results show that the models with a Pe/Py ratio
greater than 1.2 and the friction coefficient of 0.1 do not experience global buckling regardless
of the size of the gap. While loading the BRBs including the gap, severe inelastic excursions
occur in the core plate under compression, which induces lateral opening of the BRMmember.
Previous studies conducted by Korzekwa and Tremblay (2009) also confirm this phenomenon.
The results show that the overall buckling behavior of BRB models with direct contact of the
core and the BRM is more sensitive to frictional response at the interface. In the other words,
in the models without a gap at the interface, the frictional forces developed between the core
and the encasing contact surface are considerably larger in comparison to those in the models
including the gap. The excessive frictional forces generated at the interface result in the large
axial force transmission into the BRM, the development of bendingmoments in the BRM, and
the overall buckling of the entire brace, consequently.

Based on the results, the overall buckling behavior of BRBs depends on the interface detail
properties. The known parameter Pe/Py and the magnitude of friction coefficient at the core
and the BRM interface are the most effective parameters that influence the overall buckling
response of a BRB. Employing an unbonding material such as butyl rubber at the interface
provides a surfacewith a friction coefficient near 0.1. In this case, the overall buckling prevention
condition of the brace can be similar to the criterion suggested by previous researchers (i.e.,
Pe/Py ­ 1)(Watanabe et al., 1988). However, further numerical studies and experimental tests
are necessary to examine and suggest guidelines on the overall buckling prevention condition
and the design of all-steel BRBs with different interface details and various amounts of friction
coefficients at the interface, consequently.

5. Conclusions

One of the key requirements of buckling restrained braces is the performance of avoiding ove-
rall buckling until the brace member reaches target displacement and sufficient ductility. This
required performance becomes important as the BRB is lightened, and the strength and rigi-



Global buckling prevention condition of all-steel ... 901

dity of the restraining member are reduced. A new generation of BRBs, called all-steel BRBs,
is a class of BRBs with lighter buckling restraining components than conventional BRBs. In
this family of BRBs, a light steel component is used as a restraining member instead of the
mortar-filled tubes used in conventional BRBs, whichmay result in overall buckling of the brace
caused by inadequate rigidity and strength of the restraining components. In this paper, the
overall buckling prevention condition of all-steel BRBs considering the core and the encasing
interface detail is numerically examined through the finite element analysis method. Among
24 proposed all-steel BRB specimens, the models with friction coefficient of 0.1 and a Pe/Py
ratio less than 1.2 experienced global buckling during cyclic loading of the brace up to a core
strain of 2%, which closely meets the overall buckling avoidance condition of BRBs suggested
by previous researchers. However, larger Pe/Py ratios are required to prevent overall buckling
of the brace as the friction coefficient between core and BRM is increased.

Themain out-com of the study can be summarized as follows:

• Results of analysis show that for the BRM component a larger strength and stiffness is
required to inhibit global buckling of the bracewhen a higher friction coefficient or a rough
surface is specified at the core and BRM interface. The known global buckling prevention
condition of BRBs, Pe/Py > 1.2, can be applied only for braces with smooth surfaces
between the core and BRM and smaller friction coefficients, such as 0.1 and lower.

• The overall buckling response of the BRB is so sensitive to the magnitude of friction
coefficient at the interface in the case with direct contact between the core and the BRM.
In other words, the overall buckling of BRB with direct contact between at the interface
corresponds to larger values of Pe/Py in comparison to the models including a gap since
the frictional forces developed at the interface in BRBswith direct contact of the core and
BRMare higher in comparison to the BRBs including the gap. This leads to transmission
of higher axial forces into theBRMandbendingof the entire brace because of P-∆ effects.

• It is recommended to use an unbondingmaterial at the core andBRM interface to reduce
frictional forces and avoid premature overall buckling of BRBs. In addition, employing
a gap between the core and BRM not only provides enough space to accommodate free
lateral expansion of the core but also decreases the frictional forces and the chance of
global buckling of the brace for a constant stiffness and strength of the BRM as a result.
In addition, the cost of using such a material is low in comparison to the overall cost
of fabrication of a BRB. However, although using a rough material between the core and
BRMincreases themagnitudeof friction forces at the interfacewhichmay causepremature
buckling of the BRB member; it noticeably increases the energy dissipation capacity of
the brace by friction.

• Theglobal bucklingconditionof aBRBisdependenton the interface characteristics suchas
the magnitude of the friction coefficient at the interface and the gap size. Further exten-
sive experimental and numerical studies are required to survey and suggest the overall
buckling prevention condition of all-steel BRBs for design purposes considering the inter-
face properties, especially the contact characteristics between the core and the encasing
member.

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Manuscript received December 5, 2012; accepted for print February 15, 2013