Performance of stud clusters in precast bridge decks/Inkaru grupes konstrukcine charakteristika surenkamosios perdangos tiltuose/Grupveida pretbidnu veiktspeja teraudbetona tiltos ar saliekamu dzelzsbetona klatni/Poltuhenduste kaitumine eelpingestatud silladekis.
Shim, Chang-Su ; Kim, Dong-Wook ; Nhat, Mai Xuan 等
1. Introduction
Full-depth precast decks for fast bridge construction are
increasingly applied to composite bridges. Essentially, those bridges
have many connections and their structural performance is crucial not
only for structural efficiency but also for constructability. For those
bridges, shear connections between precast slabs and steel girders
typically draw a significant amount of attention from engineers. Shear
connectors are embedded in filling material in a shear pocket and impart
highly concentrated forces onto the bearing material. This concentrated
force causes the concrete to fail in tension by embedment cracking,
ripping, shear and splitting resulting in the decrease of ultimate
strength of shear connection (Oehlers, Bradford 1995). Failure modes of
the shear connection are guided according to the ratio of the shear
strength of mechanical connectors and bearing material strength.
Stud connectors are the most common type of shear connectors used
and need to be arranged according to the design provisions on minimum
and maximum pitch requirements. Due to the constraints, rigid connection
such as perfobond connectors is frequently used for high shear regions
with small area for the connectors. However, it is difficult to use the
rigid connector for the shear connection in precast decks because
reinforcement details have difficulty to be accommodated near the shear
pocket area or in the narrow joint area (Shim et al. 2001; Shim, Kim
2010; Tsujimura et al. 2000). Further, the strength of the connection is
governed by shear strength of the concrete slab in these cases. To
resolve these limitations, group stud shear connection with rather large
studs was proposed and details for the connection have been investigated
(Badie et al. 2002; Okada et al. 2006; Shim et al. 2004, 2007). The
effective shear stiffness of the connection was proposed for the
analysis of composite members (Marciukaitis et al. 2013; Shim et al.
2000).
For group stud shear connection in cast-in-place concrete slab,
test results showed that the current design provisions are applicable
for the ultimate strength and fatigue endurance when the minimum spacing
was satisfied (Okada et al. 2006; Shim, Kim 2010). In their study, the
effect of the group arrangement on static strength of stud shear
connection was not observed because of strong concrete slab. All the
specimens showed stud shank failure with minor damage of concrete slab.
They also did parametric analyses and proposed shear strength reduction
equations. However, those results were not verified through the
experiment.
[FIGURE 1 OMITTED]
[FIGURE 2 OMITTED]
Stud shear connection in precast slab bridges, material properties
of mortar in shear pockets and bedding layer should be considered for
the evaluation of structural performance of stud shear connection (Shim
et al. 2000). The thickness of the bedding layer generally varies along
the bridge because of the section change and girder connection details.
From the experiments on stud shear connection with those conditions, the
ultimate strength of the shear connection in a precast deck was 75-101%
of the tensile strength of the stud due to weaker bedding layer, and an
empirical equation only for the stud shank failure was proposed. When
the filling mortar has 1.5 times greater compressive strength than
concrete for precast decks of minimum 35 MPa, the effect of compressive
strength on the ultimate strength of the shear connection is negligible
(Shim et al. 2001).
In order to accommodate new design trends of steel-concrete
composite bridges with prefabricated concrete decks, large studs up to
31.8 mm diameter were experimentally investigated and availability of
the current design provisions for stud shear connectors was verified
based on the test results (Badie et al. 2002; Shim et al. 2004). Larose
(2006) conducted experiments on stud clusters within a circular grout
pocket. He reported that the confinement by a steel tube enhanced the
shear strength of the grouped stud shear connection.
The failure modes of shear connection are categorized as shown in
Fig. 1. Mode 1 is defined as stud failure without considerable concrete
damage. Mode 3 means the concrete failure without stud failure. When the
connectors are failed after considerable concrete damage, it is defined
as Mode 2. When the post-cracking strength of the concrete slab is
enough to resist shear strength of stud connectors, Mode 2 is expected.
Therefore, it is necessary to increase shear strength of concrete slab
to utilize the shear strength of stud clusters.
Recently, the full-depth precast decks have been increasingly
applied to twin-girder bridges and open-box girder bridges. It reduces
the construction cost by about 15-20% but several difficulties need to
be solved. In order to satisfy the design requirements for composite
action, it is necessary to place 6-8 shear pockets in each precast slab
even when 25 mm studs are used. In a precast deck these pockets reduce
the flexural stiffness resulting in cracking during delivery and
erection process. The precast decks need longitudinal post-tensioning
essentially and transverse pretensioning for wider decks (Shim, Chang
2003). Therefore, clustered stud arrangement of stud connectors is
essential to solve the complex details. The previous empirical equation
did not consider this case (Shim, Kim 2010).
Fig. 2 shows the typical examples of the shear connection detail
dealt in this paper. Details of the deck are very complicated and need
to be simplified by reducing the number of the shear pockets. One of the
critical constraints for the simplification is the minimum pitch
requirement of stud connectors in a shear pocket. The current minimum
stud spacing is for shear connection in cast-in-place concrete slab.
Maximum aggregate size and weld ability of the connectors using a
welding gun are considered in this requirement. However, the shear
connection for precast decks has high strength mortar around stud
connectors. The minimum spacing is reduced only if the reduction of
shear strength of the shear connection is considered. In order to reduce
the number of shear pockets for the simpler details of precast slabs, it
necessary to verify fatigue endurance of the connection for the reduced
spacing. The reduction of static strength of the shear connection
considering the reduced spacing does not significantly increase number
of connectors because the fatigue endurance governs the design of shear
connection.
In this paper the effects of the stud spacing on the static and
fatigue performance were investigated. The group arrangement of stud
connectors for prefabricated concrete slab was considered, including
confining internal and external reinforcing bars to increase bearing
strength and shear strength of the concrete slab, respectively. A new
empirical equation for the clustered stud shear connection considering
the reduced stud spacing was proposed. Fatigue tests were also conducted
to verify the fatigue strength of group stud shear connection.
2. Experimental program
2.1. Static tests of shear connection
The experimental program consists of three series (G, GCIP, and S).
G specimens deal with grouped stud shear connection for precast decks
and GCIP for cast-in-place concrete decks (Shim, Kim 2010). The effect
of stud spacing need to be estimated when concrete slab has a
significant damage in bearing zone or splitting cracks in the direction
of shear force, which is shown in Fig. 1b. S specimens had larger stud
spacing in order to neglect effects of the group arrangement on static
strength of shear connection. Table 1 summarizes the push-out specimens
to investigate static behaviour of shear connection. In addition,
previous test results (Shim et al. 2001) were used to evaluate the
effects of the design parameters on static and fatigue strength of the
shear connection.
Push-out specimens were fabricated to execute static tests for the
evaluation of shear strength of shear connection with clustered stud
arrangement. Fig. 3 shows the push-out specimen for precast decks.
Precast decks with 250 mm thickness were prefabricated and were combined
with steel beam by filling non-shrink mortar in shear pockets. Nine
clustered studs with 25 mm and 22 mm diameter were welded on flanges and
stud pitch was varied to have 5[d.sub.s], 4[d.sub.s] and 3[d.sub.s]
([d.sub.s] is stud diameter in mm). Even though the mortar fills the
shear pocket with narrow space, it is impossible to allow the stud
spacing less than 3[d.sub.s] due to the limitation on welding by a
welding gun.
As mentioned before, it is necessary to prevent premature failure
of bearing zone and concrete slab. In order to increase the strength of
mortar and the shear strength of the concrete slab, constraining
reinforcements were arranged inside and outside the shear pockets, as
presented in Fig. 4. External reinforcements were placed before casting
concrete of the precast slabs. Internal reinforcements were put in the
shear pockets after placing the slab on a steel beam. Dimensions of the
shear pocket were the same for all the specimens.
For the grouped stud shear connection in cast-in-place deck (GCIP
specimens in Table 1) nine 25 mm studs are arranged to satisfy the
minimum pitch requirements. Longitudinal and transverse spacing is 125
mm and 62.5 mm, respectively. To prevent severe damage of the concrete
slab, 16 mm reinforcing bars are placed at the top and bottom concrete
slab. The slab has 400 mm thickness and the design compressive strength
of concrete is 40 MPa. Average compressive strength of concrete was 57.6
MPa resulting in minor damage in concrete slab. S22A and B specimens are
for the single arrangement in precast decks. Stud spacing was thirteen
times greater than stud shank diameter.
[FIGURE 3 OMITTED]
[FIGURE 4 OMITTED]
In order to ensure quality of cast-in-place mortar and enough
strength for the bearing zone of studs, filling mortar had 1.5 times
greater than the compressive strength of concrete for precast decks.
From previous research (Shim et al. 2000), higher strength of mortar do
not increase the shear strength of shear connection if the failure mode
is stud shank failure. Yield strength of the reinforcement for all
specimens is 450 MPa and tensile strength of stud connectors was 426
MPa.
Static tests of push-out specimens were performed in a hydraulic
testing machine with a 10 000 kN capacity. Subsequent load increments
were imposed such that failure does not occur in less than 15 min
according to EN 1994-1:2004 Eurocode 4: Design of Composite Steel and
Concrete Structures--Part 1: General Rules and Rules for Buildings.
Longitudinal slips between each concrete slab and steel section were
measured continually during loading or at each load increment using four
1/1000 mm LVDTs. The slip was measured at least until the load had
dropped to 20% below the maximum load.
2.2. Fatigue tests of shear connection
Two sets of test specimens were fabricated to estimate the effect
of stud spacing on the fatigue endurance of grouped stud shear
connection, as presented in Table 2. Dimensions and material properties
of the fatigue specimens were the same as those of static test
specimens.
To assess the effect of grouped arrangement with reduced stud
spacing, the previous experimental results on fatigue strength of shear
connection were utilized (Lee et al. 2005; Shim et al. 2000, 2001).
Among the test results, 25 mm stud connectors were selected for the
comparison with current test results. FG25OS specimens had external
reinforcements to strengthen the shear capacity of concrete slab.
3. Test results
3.1. Static behaviour of grouped stud shear connection
Two series of test specimens showed different failure modes
according to relative strength ratio between concrete slab and stud
connectors. Fig. 5 shows typical three failure modes of the shear
connection from the static tests of G series.
Table 1 summarizes the test results in terms of shear strength,
slip capacity and failure mode. Shear connection in a shear pocket
showed behaviour of a block connector due to high strength mortar and
internal reinforcements as shown in Figs 5c-5d. Mode 2 in Table 1 means
that there was stud shank failure with severe cracking of concrete slab.
Grouped stud shear connection with precast slabs had severe concrete
cracking. Average shear strength of Push-out specimens with
cast-in-place slab was 1.7 times greater than G25 specimens with the
same stud spacing. Therefore, Eq (1) needs to be changed to consider
concrete strength by using a common parameter of [square root of
[f.sub.cm][E.sub.cm]] as specified in the design code EN 1994-1:2004.
Instead of strength of concrete slab, the compressive strength of mortar
([f.sub.cm], N/[mm.sup.2]) should be included for the shear connection
of precast decks.
[FIGURE 5 OMITTED]
For group stud connection of precast decks, closer pitch reduced
the shear strength up to 30% when the failure mode is stud failure after
concrete cracking of the slab. External reinforcements increased
post-cracking strength of the concrete slab while internal reinforcement
increased bearing strength a little. Therefore, it is important to
strengthen the concrete slab when group stud connectors are used. When
the failure mode is splitting failure of the concrete slab without stud
failure, current design provisions on shear strength of concrete slab
according to EN 1994-1:2004 are appropriate to evaluate the strength of
the connection.
Fig. 6 represents the load-slip curves of the static test
specimens. From the curves of 25 mm studs with stud spacing of 5
[d.sub.s], external and internal reinforcements showed 17.9% and 10%
increase of the static strength respectively comparing to the specimens
without additional reinforcement. The confining reinforcements increased
the shear strength of concrete slab and bearing strength of mortar
resulting in the change of failure mode from Mode 3 to Mode 2. For 25 mm
studs with stud spacing of 3[d.sub.s], external and internal
reinforcements showed 23% and 13% increase of the static strength,
respectively. Shear connection with internal reinforcement showed stable
behaviour after peak load. However, specimens with 22 mm studs showed
negligible increase of shear strength by additional reinforcement. These
specimens showed stud shank failure with minor damage in concrete slab.
[FIGURE 6 OMITTED]
Decrease of stud spacing from 5[d.sub.s] to 3[d.sub.s] reduced the
shear strength of the shear connection by 7% for a standard specimen,
4.4% for internal reinforcing and 3.0% for external reinforcing. For the
shear connection with 22 mm studs, the shear strength was reduced by
6.5% by decreasing the stud spacing from 4[d.sub.s] to 3[d.sub.s]. This
reduction is considered to propose the empirical equation. Filling
material in shear pockets for stud connectors is required to have
greater compressive strength than that of concrete for precast decks
(Shim et al. 2001). From the observation of the static tests, grouped
stud shear connection including mortar in the pocket showed similar
behaviour to a block connector. Therefore, it is more effective to
strengthen the connection by placing confining reinforcement around the
shear pocket.
Ultimate slip capacity of the shear connection is defined as the
slip when the shear load is reduced by 10% from its peak (Oehlers,
Bradford 1995). According to EN 1994-1:2004 a ductile connection is
defined by the ultimate slip capacity greater than 6.0 mm. All the
specimens which had Mode 1 failure showed enough slip capacity to ensure
ductility of the connection, as summarized in Table 1.
3.2. Empirical equation for group stud shear connection in precast
decks
In order to allow the particular design situation of closer stud
spacing than the current design requirement, it is necessary to provide
an empirical equation for static strength of the shear connection in
precast decks. Previous test results on stud shear connection in precast
slabs (Hanswille et al. 2007; Shim et al. 2000, 2001) were included in
the analysis. As shown in Fig. 7, the empirical equation from the
previous research (Shim et al. 2000) showed good agreement with test
results of shear connection with wider stud spacing but overestimated
the shear strength of the shear connection with clustered stud
arrangement as presented in Fig. 7b. Therefore, an additional
modification factor is needed to evaluate the effect of closer stud
spacing.
[FIGURE 7 OMITTED]
In order to investigate the effect of stud spacing, the reference
values were collected from the previous tests (Shim et al. 2000, 2001).
The modification factor ([[beta].sub.s]) for stud spacing is assumed to
be 1.0 when the pitch is wider than five times of stud shank diameter.
An empirical Eq (1) for the reduction factor of stud spacing is proposed
by linear regression analysis as shown in Fig. 8. When the stud pitch is
smaller than 5 times of stud diameter, strength reduction of the shear
connection is evaluated using the proposed equation. The equation only
considers stud failure after concrete cracking. Therefore, it is
necessary to check shear strength of concrete slab to utilize this
equation.
[MATHEMATICAL EXPRESSION NOT REPRODUCIBLE IN ASCII], (1)
where s--pitch of stud connectors, mm; [d.sub.s]--the stud shank
diameter, mm.
[FIGURE 8 OMITTED]
From the observation of static tests it is preferable to strengthen
the concrete slab for group stud shear connection to ensure ductile
behaviour and greater shear strength. Compressive strength of mortar
should be 1.5 times greater than that of concrete slab in order to
provide enough bearing strength. In actual precast decks, transverse
reinforcements around shear pockets need to be checked to have enough
shear strength to resist the grouped stud shear connection according to
the design codes EN 1994-1:2004. Based on these two requirements, a new
empirical equation for Mode 1 and Mode 2 failure is needed to consider
structural characteristics of shear connection in precast decks. Even
though the strengthening of concrete slab increases the shear strength
of the shear connection, it is necessary to be considered as a detail
requirement and a safety margin which is similar to the design codes.
Combining two empirical equations for the stud shear connection in
precast decks an empirical model (4) was proposed to evaluate the shear
strength considering filling material in shears pockets, bedding height
and stud spacing. The equation assumes the failure Mode 2 and nonshrink
mortar as a filling material in shear pockets. As specified in current
design codes EN 1994-1:2004 the upper limit of the shear strength is:
[P.sub.Rd] = [[0.8[f.sub.u][pi][d.sup.2.sub.s]]/4] /
[[gamma].sub.v], (2)
where [[gamma].sub.v]--partial safety factor; [d.sub.s]--diameter
of the shank of the stud; [f.sub.u]--specified ultimate tensile strength
of the material of the stud.
Instead of material properties of concrete, compressive strength
and elastic modulus of mortar are used.
[P.sub.e] = [k.sub.c][P.sub.t] =
[k.sub.c][[alpha].sub.b][[beta].sub.s][d.sup.2.sub.s][square root of
[f.sub.cm][E.sub.cm]] (3)
where [[alpha].sub.b] = 1 - 0.0086([B.sub.h] - 20)--for bedding
thickness effect; [[beta].sub.s]--for stud spacing effect as shown in Eq
(1); [f.sub.cm]--compressive strength of mortar using a 50 mm cubic
mould, MPa; [E.sub.cm] = 3.26 x [10.sup.3] [square root of
[f.sub.cm]]--elastic modulus of mortar, MPa (Shim et al. 2000).
As mentioned before, shear strength of grouped stud shear
connection in precast decks is lower than that of normal shear
connection with cast-in-place concrete slab. Statistical analysis for
the empirical equation was executed in accordance with Annex D of EN
1990:2002 Basis of Structural Design. Thirty eight test results of shear
connection in precast decks including previous test results (Hanswille
et al. 2007; Shim et al. 2000) were used for the analysis. As shown in
Fig. 9, the factor [k.sub.c] of Eq (3) results to 0.22, while the
current value in EN 1994-1:2004 is 0.29. The mean shear strength of the
shear connection for precast decks was suggested as Eq (4) in the range
of test parameters in this paper. The factor [k.sub.c] is determined
according to test results used for the statistical analysis. Therefore,
it is necessary to have more experimental data to propose a design
equation based on Eq (4):
[P.sub.e]=0.22[[alpha].sub.b][[beta].sub.s][d.sup.2.sub.s][square
root of [f.sub.cm][E.sub.cm]], (4)
where [[alpha].sub.b] = 1 - 0.0086([B.sub.h] - 20)--for bedding
thickness effect; [[beta].sub.s]--for stud spacing effect as shown in Eq
(1); [d.sub.s]--diameter of the shank of the stud;
[f.sub.cm]--compressive strength of mortar using a 50 mm cubic mould,
MPa; [E.sub.cm] = 3.26 x [10.sup.3] [square root of [f.sub.cm]]--elastic
modulus of mortar, MPa (Shim et al. 2000).
The empirical equation for the clustered shear studs in precast
decks will give 24% lower strength than the value from EN 1994-1:2004.
It is necessary to design concrete slab to have enough shear strength to
resist the ultimate shear strength of the clustered connectors by
constraining reinforcements. The shear strength of the shear connection
was increased through the use of higher strength mortar and confining
reinforcing bars around shear pockets (Nguyen et al. 2009).
According to the test results by Larose (2006), stud clusters with
steel tube confinement showed significant increase in shear strength of
stud shear connection. A steel tube with 200 mm diameter and 1.6 mm
thickness was used for the confinement of 16 mm stud connectors. 6 to 10
stud connectors were arranged in a shear pocket. Average cylinder
strengths for the grout in shear pockets ranged from 48.7 MPa to 68.9
MPa. Fig. 10 shows the comparisons of test results and calculated values
by Eq (3) according to different confinement methods. The results showed
the extreme confinement increased the shear strength. Therefore, failure
mode and its shear strength of grouped stud shear connection are
effectively controlled by adding confinement as presented in Fig. 11 as
an example design of a prefabricated prestressed concrete slab.
3.3. Fatigue endurance
Normally, the stud pitch is determined from the fatigue design.
Minimum requirement for welding of studs using a stud gun is around 3ds.
When the static failure mode of the shear connection is stud failure
with negligible damage of concrete slab, fatigue endurance of the shear
connection with group arrangement is expected to be similar to that of
normal arrangement. Push-out specimens with cast-in-place concrete slab
showed much higher fatigue strength than the current design codes (Shim,
Kim 2010). As shown in Fig. 12a, the concrete damage was not overlapped
and remained in a sound state after fatigue failure of stud connectors.
Therefore, the current design provisions on fatigue strength of stud
connectors are applicable to the design of the group stud shear
connection when the minimum spacing is satisfied and concrete slab has
enough strength to resist the shear load.
[FIGURE 9 OMITTED]
[FIGURE 10 OMITTED]
[FIGURE 11 OMITTED]
[FIGURE 12 OMITTED]
[FIGURE 13 OMITTED]
Damage overlapping of bearing zone was observed for the group stud
shear connection in precast decks as presented in Figs 12b-12c. All the
specimens had no shear failure of concrete slab. As stud spacing is
closer, damage overlapping was significant and resulted in lower fatigue
strength than the previous test results for normal arrangement (Shim et
al. 2000). Damage in bearing zone of shear connection induces the higher
stress concentration in weld collar of stud connectors.
Fig. 13 shows S-N curves of clustered stud shear connectors with
closer spacing. Comparing with previous test results for single
arrangement in a precast deck (Shim et al. 2001), clustered shear studs
with closer spacing showed lower fatigue strength. However, the fatigue
strength of the clustered studs in precast decks gave similar results
from EN 1994-1:2004. However, it is essential to have careful
considerations for the design of clustered shear studs in prefabricated
slabs because the safety margin of fatigue endurance is decreased
significantly judging from the test results. Without significant
reduction of fatigue strength, it is possible to utilize the clustered
shear studs for precast deck bridges when stud pitch is greater than
3[d.sub.s].
4. Conclusions
1. For the design of full-depth prefabricated concrete slabs,
simplification of details in precast decks is crucial for the
constructability. Considering filling material in shear pockets for
clustered shear studs, it is possible to use closer stud spacing than
the current design provisions. The effects of the stud spacing on the
static and fatigue performance of shear connection in precast decks were
investigated through tests and previous data. For the shear connection
of precast deck bridges, the effects of the stud spacing and confining
reinforcements were clearly observed. Decreasing the stud spacing
resulted in a lower ultimate strength of the shear connection. For
clustered stud connection of precast decks, closer spacing reduced the
shear strength by up to 30% when the failure mode is stud failure after
concrete cracking of the slab. The confining reinforcements inside and
outside of the shear pocket enhanced the shear strength of the shear
connection. It is more effective to strengthen the connection by placing
confining reinforcement around the shear pocket.
2. The requirement of the minimum pitch for the stud connectors
needs to be revised for precast decks. However, the shear connection
with smaller spacing should have adequate reinforcement details to
resist shear strength of group stud shear connectors. Considering
filling material in shear pockets, bedding height and stud spacing,
empirical equations for the evaluation of static performance of shear
connection in precast decks were proposed.
3. Fatigue tests showed that the connectors in precast decks gave
relatively lower fatigue strength than normal shear connection in
cast-in-place concrete slab. In the range of test parameters of this
paper, current S-N curves for the fatigue design of common stud
connectors are applicable to the design of shear connection in precast
decks.
4. Design recommendations on details were suggested to enhance the
structural performance of shear connection in precast slabs. Reasonable
safety margin is essential for the design of modular structures
considering difficulties of quality control of connections in a
construction field. Further experiments are needed to derive a design
equation considering strengthening details such as high strength filling
material and extreme confinement by a steel tube.
Caption: Fig. 1. Failure modes of shear connection: a--stud
failure; b--stud failure after cracking; c--concrete failure
Caption: Fig. 2. Shear connection for precast deck
Caption: Fig. 3. Push-out specimens
Caption: Fig. 4. Details of confining reinforcement: a--external
reinforcements; b--internal reinforcement
Caption: Fig. 5. Failure patterns of group stud shear connection in
precast deck: a--G25OS-1 (Mode 1); b--GS25IS-2 (Mode 2); c--G25NS (Mode
3); d--effect of internal reinforcement
Caption: Fig. 6. Load-slip curves according to strengthening
details: a--25 mm stud--3[d.sub.s], 5[d.sub.s]; b--22 mm
stud--3[d.sub.s], 4[d.sub.s]
Caption: Fig. 7. Comparison of test results with previous empirical
equation by Shim (2000): a--single arrangement of studs; b--group
arrangement of studs
Caption: Fig. 8. Results of the statistical analysis
Caption: Fig. 9. Shear strength of group stud shear connection
Caption: Fig. 10. Comparisons of shear strength according to
confinement methods
Caption: Fig. 11. Detail recommendation for shear connection in
precast decks
Caption: Fig. 12. Fatigue failure pattern of group stud shear
connection: a--FGCIP-3; b--FG25OS-1; c--FG25OS-4
Caption: Fig. 13. Fatigue test results of clustered shear studs in
precast decks
doi:10.3846/bjrbe.2014.06
Received 12 December 2011; accepted 8 April 2013
Acknowledgement
This research was supported by a grant from the R&D Policy and
Infrastructure Development Program (11-09-01-Development of Performance
based design codes on steelconcrete composite structures) funded by the
Ministry of Land, Infrastructure and Transport (MOLIT) of the Korean
Government.
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Journal of Constructional Steel Research 57(3): 203219.
http://dx.doi.org/10.1016/S0143-974X(00)00018-3
Shim, C. S.; Kim, J. H.; Chung, C. H.; Chang, S. P. 2000. The
Behavior of Shear Connection in Composite Beam with FullDepth Precast
Slab, Structures and Buildings, the Institution of Civil Engineers
140(1): 101-110. http://dx.doi.org/10.1680/stbu.2000.140.L101
Tsujimura, T.; Shoji, A.; Noro, T.; Muroi, S. 2002. Experimental
Study on a Joint in Prestressed Concrete Bridge with Steel Truss Web, in
Proc. of the 1st Congress, Composite Structures Ed. by Japan Prestressed
Concrete Engineering Association. October 13-19, 2002, Osaka: Osaka
Prefectural Government, 347-352.
Chang-Su Shim (1) ([mail]), Dong-Wook Kim (2), Mai Xuan Nhat (3)
(1) School of Civil and Environmental Engineering, Urban Design and
Study, Chung-Ang University, 84 Heukseok-Ro, Seoul, 156-756, Korea
(2,3) Dept of Civil Engineering, Chung-Ang University, 84
Heukseok-Ro, Seoul, 156-756, Korea
E-mails: (1) csshim@cau.ac.kr, (2) clearup7@cau.ac.kr, (3)
nhatmaixuan@cau.ac.kr
Table 1. Static test specimen for precast decks
Specimen [d.sub.s], [f.sub.cm], [f.sub.c]',
mm N/[mm.sup.2] N/[mm.sup.2]
G25NS 25 49.5 32.6
G25OS 25 49.5 32.6
G25IS 25 49.5 32.6
G25OS-1 25 49.5 32.6
G25NS-2 25 49.5 32.6
G25OS-2 25 49.5 32.6
G25IS-2 25 49.5 32.6
G22OS 22 49.5 32.6
G22IS 22 49.5 32.6
G22OS-1 22 49.5 32.6
G22IS-1 22 49.5 32.6
GCIP1-1 25 -- 57.6
GCIP1-2 25 -- 57.6
GCIP2-1 25 -- 57.6
GCIP2-2 25 -- 57.6
GCIP3-1 25 -- 57.6
GCIP3-2 25 -- 57.6
S22A 22 61.09 35.8
S22B 22 61.09 35.8
Specimen [B.sub.h] [Q.sub.u] [[delta]
mm kN .sub.u], mm
G25NS 20 115.1 5.00
G25OS 20 135.6 3.60
G25IS 20 126.5 10.73
G25OS-1 20 105.1 3.52
G25NS-2 20 107.0 4.11
G25OS-2 20 131.6 3.61
G25IS-2 20 120.9 9.30
G22OS 20 119.9 6.67
G22IS 20 119.4 5.65
G22OS-1 20 110.9 7.56
G22IS-1 20 112.2 28.75
GCIP1-1 -- 220.0 14.50
GCIP1-2 -- 227.8 11.21
GCIP2-1 -- 233.4 17.45
GCIP2-2 -- 206.8 14.55
GCIP3-1 -- 203.0 14.00
GCIP3-2 -- 241.5 12.06
S22A 20 141.6 7.26
S22B 20 154.7 8.14
Specimen S, Details Failure
mm modes
G25NS No * Mode 3
G25OS 5[d.sub.s] Ext ** (D16) Mode 2
G25IS Int *** (D10) Mode 2
G25OS-1 Ext(D16) Mode 1
G25NS-2 No Mode 2
G25OS-2 3[d.sub.s] Ext (D16) Mode 2
G25IS-2 Int (D10) Mode 2
G22OS 4[d.sub.s] Ext (D16) Mode 1
G22IS Int (D10) Mode 1
G22OS-1 3[d.sub.s] Ext (D16) Mode 1
G22IS-1 Int (D10) Mode 1
GCIP1-1 No Mode 1
GCIP1-2 No Mode 1
GCIP2-1 5[d.sub.s] Ext (D16) Mode 1
GCIP2-2 Ext (D16) Mode 1
GCIP3-1 Ext (D16x2) Mode 1
GCIP3-2 Ext (D16x2) Mode 1
S22A 13[d.sub.s] No Mode 1
S22B No Mode 1
Notes: * No--no additional reinforcement; ** Ext--external
reinforcements added; *** Int--internal reinforcement added.
Table 2. Fatigue test specimens
Specimen Compressive Compressive Stud
strength of strength of spacing
mortar, MPa concrete, MPa
FG25OS-1 49.5 32.8 4[d.sub.s]
FG25OS-2 49.5 32.8 4[d.sub.s]
FG25OS-3 49.5 32.8 3[d.sub.s]
FG25OS-4 49.5 32.8 3[d.sub.s]
FGCIP-1 -- 57.6 5[d.sub.s]
FGCIP-2 -- 57.6 5[d.sub.s]
FGCIP-3 -- 57.6 5[d.sub.s]
Specimen Concrete slab Reinforcement Stress
detail range, MPa
FG25OS-1 Precast Ext. 130
FG25OS-2 Precast Ext. 150
FG25OS-3 Precast Ext. 130
FG25OS-4 Precast Ext. 150
FGCIP-1 Cast-in-place No 140
FGCIP-2 Cast-in-place No 150
FGCIP-3 Cast-in-place No 160
