13th World Conference on Earthquake Engineering Vancouver, B.C., Canada
August 1-6, 2004 Paper No. 1277
DESIGN FOR STRUCTURAL PERFORMANCES OF REINFORCED CONCRETE FRAME WITH CAST-IN-PLACE NON-STRUCTURAL
REINFORCED CONCRETE WALLS
Tomoaki SUGIYAMA1, Yasuhiro MATSUZAKI2, Katsuhiko NAKANO3
SUMMARY In the Japanese conventional cast-in-place reinforced concrete (RC) buildings, RC frames (columns and beams) and cast-in-place non-structural RC walls (mullions, spandrels and sidewalls) were constructed simultaneously, so they were connected rigidly. In the past earthquake, in cases where the shear reinforcement of column is enough to resist the shear force, it is reported that the damage of columns and beams was slight due to the failure of cast-in-place non-structural RC walls. So, the purpose of this research is controlling the failure mode of cast-in-place non-structural RC walls and using the cast-in-place non-structural RC walls to a seismic design positively, such as a rise of stiffness, capacity and energy dissipation. Then this paper proposed a method to estimate the structural performance of the RC frames with cast-in-place non-structural RC walls. As described above, The shear-loading tests for one-story RC frames with cast-in-place non-structural walls were conducted. Eight specimens, which were modeled with a scale of 1/3, were prepared. The parameters was set in the test were the shear reinforcement of column and the shapes of non-structural walls. From the test, it was proved that the non-structural RC walls could advance the structural performance of RC frames, and the stress of column and non-structural walls were clarified. The finite element analysis (2-D non-linear analysis) was conducted, in order to compensate tests. The analytical results agreed with test results, and the parametric analytical results were more useful to clear the internal stress. Then, the shear resistant mechanism of RC frames and non-structural RC walls was clarified with test results and analytical results. Still more, this paper propose the method to predict the structural performance (the load-displacement relationship) of RC frames with non-structural RC walls by the shear resistant mechanisms.
INTRODUCTION In the Japanese conventional cast-in-place reinforced concrete (RC) buildings, RC frames (columns and beams) and cast-in-place non-structural RC walls (mullions, spandrels and sidewalls) are constructed
1 Research Assoc., Tokyo University of Science, Tokyo, JAPAN Email: [email protected] 2 Professor, Tokyo University of Science, Tokyo, JAPAN Email: [email protected] 3 Assoc. Professor, Niigata Institute of Technology, Niigata, JAPAN Email: [email protected]
simultaneously, and they are connected rigidly. So, the stress transfer exists between the RC frame and the cast-in-place non-structural walls (mullions, spandrels and sidewalls), and the cast-in-place non-structural walls influences the seismic behavior of the RC structures. In the past earthquake, the shear failure of the column with non-structural walls (ex. shear failure of short column; column with spandrels) was reported as one example of the influence. However, in cases where the shear reinforcement of the column is enough to resist the shear force, it is reported that the damage of columns and beams was slight by cast-in-place non-structural RC walls failed, for example [AIJ, 1 and 2]. On the other side, there are no evaluation methods for designing structural performance (stiffness, capacity, failure mode and ductility) of the RC frame with cast-in-place non-structural RC walls, because the shear resistant mechanism of RC frame (columns and beams) with cast-in-place non-structural RC wall was not clarified. Though it has been recommended as the conventional method to use isolation detail (called slit) between cast-in-place non- structural RC walls and RC columns, serious damages were observed in the buildings where the detail of the isolations were not suitable detail, for example [AIJ, 2]. So, the purpose of this research is controlling the failure mode of cast-in-place non-structural RC walls and using the cast-in-place non-structural RC walls to a seismic design positively, such as a rise of stiffness, capacity and energy dissipation. Then this paper proposed a method to estimate the structural performance of the RC frames with cast-in-place non-structural RC walls.
TEST OF SERIES-1[2] The purpose of this test is to clarify the performance, the structural performance of the RC frame with cast-in-place non-structural RC walls and the damage performance of the cast-in-place non-structural RC walls. This test is reported [Sugiyama et al., 3], and here, especially describes the structural performance of the RC frame with cast-in-place RC walls. Outline of the specimen Details of specimens in series-1 are shown in Fig.1. The specimen was a one-story one-span RC frame. The specimen No.0-0 was the open RC frame, and the specimen No.1-1 was the RC frame with cast-in-place shear wall. The specimen No.1-2 and No.1-3 were the RC frame with cast-in-place non-structural RC walls, which was supposed a frame in the apartment houses. The specimen No.1-2 was spandrel type
Fig.3: Shear force(Q)-Displacement(δ ) relationship skeleton curve
0
200
400
600
800
1000
0 10 20 30 40 50 60
R[rad.] 1/25 1/50 1/100 1/200
No.1-1 Shear
No.1-2 Spandrels No.1-3 Sidewalls
No.0-0 Frame
R
Q/2 Q/2
δ [mm]
Q[kN]
No.1-1 Shear Wall
No.1-3 Sidewalls
No.1-2 Spandrels
(R=+1/25rad.) Fig.2: Crack Patterns
(Series1) Fig.1: Detail of specimens
No.1-1 Shear Wall
No.1-3 Sidewalls
No.1-2 Spandrels
t=60, D6@ 200
t=40, D4@ 105
t=40, D4@ 105
480 370
840
280
260
840
280
840
280
260
specimen, and the specimen No1-3 was sidewall type specimen. The column and beam of the frame were unified in all specimens. The cross section of column (BC x DC) was 240mm x 240mm, and the cross section of beam, to be made quite stiff, (BB x DB) was 800mm x 600mm. The thickness of shear wall was 60mm, and the thickness of non-structural walls was 40 mm. The reinforcement bar of RC walls were anchored a column and beams, and the length of the anchor was 210mm. The length of RC wall was 1760mm, and the height was 1100mm. Concrete strength was from 24.1 to 33.0 N/mm2. Result of the test Crack patterns are shown in Fig.2. In the specimen No.1-2 (spandrel type), shear cracks in mullion and spandrel were observed around 1/800rad. in story drift angle. Finally, the decrease of shear force was caused by the compressive failure of column-spandrel connection concrete. In the specimen No.1-3 (sidewall type), shear cracks and flexural compressive failure of sidewall concrete were observed. Next, shear cracks developed along the vertical reinforcing bar in the sidewall. Finally the column and the side-wall slid off vertically. Failure mode of the specimen No.0-0 (frame), No.1-2 and No1-3 were the flexural yield of column, and that of the specimen No.1-1 (shear wall) was the shear failure of shear wall. Shear force (Q) – story displacement ( δ ) relationship skeleton curves are shown in Fig.3. The initial stiffness of non-structural wall specimens (No.1-2 and No.1-3) was higher than that of the frame specimen, and were similar to that of the shear wall specimen (No1-1). Reduction in the stiffness was observed around 1/800rad. in story drift angle due to the failure of non-structural RC walls (mullion, spandrel and sidewall). After maximum load, the shear force decreased slowly, but it was rather higher than the flexural strength of frame specimen. Furthermore, the energy dissipation of non-structural specimen (No1-2 and No1-3) was higher than that of the frame specimen, and it means that the hysteresys of non-structural wall specimens were ductile. Those result suggested that the structural performance (stiffness, capacity and energy dissipation) of RC frame with cast-in-place non-structural RC walls (spandrels and sidewalls) is advanced from that of the open RC frame, if the column has the shear reinforcement which can resist the shear force.
TEST OF SERIES-2 The purpose of this test is to suggest the influence of principal factor, the shear reinforcement of column and the shape of cast-in-place non-structural RC wall, to the structural performance of RC frame . Outline of the test The specimen in series-2 test was designed by referring to series-1 test. The variable in this test, the shear reinforcement of column and the shape of cast-in-place non-structural RC wall, was set including the specimen in series-1. Specimen Fig.4 shows the detail of specimen in series-2. The shape of RC frame, the column and the beam, was due to series-1. The specimen with a scale of 1/3 was a frame with cast-in-place non-structural wall. The columns, the beams and non-structural walls were cast simultaneously. The reinforcement bar of RC walls were anchored a column and beams, and the length of the anchor was 210mm. The height of column was 1100mm, and the clear span of beam, the length of RC walls, was 1760mm. The specimen No.2-1 and No.2-2 were the one-story one-span RC frame, and the specimen No.3-1 and No.3-2 were the one-story two-span RC frame (added the center column). The variables were the shear reinforcement of the column, the thickness of cast-in-place non-structural walls (spandrel) and the side of column connected spandrels (column of internal/exterior). In the sidewall type specimen (No.1-3, No.3-2), the length of sidewall was
added to the variables. The shear reinforcement ratio (pw) of column of the specimen No.2-1 were 0.38%, that of the specimen No.2-2 was 0.19%, and that of the specimen No.3-1 and No.3-2 was 0.89%. The thickness (t) of non-structural wall (spandrels and sidewall) was 40mm, 60mm and 80mm. The length of sidewall was 240mm (1.0 DC, DC: depth of column), 360mm (1.5 DC) and 470mm (nearly 2.0 DC). As shown in the fig.4, The spandrels were planned to observe the influence to the behavior of the column of the thickness of spandrels on each direction of loading (plus cycle and minus cycle). The sidewalls were planed to observe the influence to each column of the thickness and the length of sidewall.
Table1: Detail of specimens in series-2 Column Non-structural walls
No. (Column)
Concrete Strengthen[N/mm2]
Shear Reinforcement (Hoop) pw[%]
thickness t
[mm]
Reinforcement (ps)[%]
Left 40 D4@105 (0.30%) 2-1
Right
D6@70 0.38% 80 D4@105
(0.15%)
Left 40 D4@105 (0.30%) 2-2
Right
27.8
D6@140 0.19%
80 D4@105 (0.15%)
40 D4@105 (0.30%) 3-1
Right, Center Left
33.4 60 D4@105
(0.20%) Right Center 40 D4@105
(0.30%) 3-2 Left
33.9
Section BC xDC
mm x mm 240
x 240
Longitudinal
Bar 12-D13 (4-D13)
pt=0.88% D6@30 0.89%
60 D4@105 (0.20%)
Strengthen of concrete was based on cylinder test piece which are the diameter of 10mm and a height of 20mm.
Fig.5: Loading apparatus
Shear loading
jack
Shear loading
jack
Axial loading
jack
Confining out-of
-plane
deformation
Loading beam
2000
1400
600
Table2: Mechanical properties of reinforcement
No. Reinforcement Section
Aria [mm2]
Yield Strengthen [N/mm2]
Tensile Strengthen [N/mm2]
Shear reinforcement of walls (D4) 12.5 252 292
Shear reinforcement of column (D6) 32 303 497 2-1 2-2
Longitudinal bar of column (D13) 127 384 510
Shear reinforcement of walls (D4) 12.5 228 300
Shear reinforcement of column (D6) 32 296 473 3-1 3-2
Longitudinal Bar of column (D13) 127 376 529
D4 is 4mm in diameter deformed bar; D6 is 6mm in diameter deformed bar; D13 is 13mm in diameter deformed bar.
600
110
0
14
00
600
12-D13
D6@70
12-D19
D13
@100
2-D10 24
0
240
80
240
240
40
t=4
D4@105
t=8D4@105 3
70
12-D13
D6@140
t=4D4@105
t=8
D4@105 37
0
No.2-1
No.2-2
No.3-1
No.3-2
240 240 380 240 380 760 760
12-D13
D6@30
37
0
t=60 D4@
105 t=40
t=40
t=6
D4@
105
240 1760 380 240 380
500 2000 500
240 240 380 240 380 240 240 360 360 160 160
12-D13
D6@30
t=40
105
t=60
105
t=40
D4@ D4@
Fig.4: Detail of specimens in series-2 (Dimension: mm)
Method of the test Fig.5 shows the loading apparatus. The axial load, kept constant during the test (N=2or3 x BC x DC x fC’/6), was applied to specimen by two jacks. The lateral (shear) load was applied to the specimen by horizontal jacks on loading beam. In the plus cycle, the specimen was loaded from left to right, and in minus cycle, the specimen was loaded from right to left. The shear cyclic loading was controlled by story drift angle, and the maximum story drift angles (R) in cycles were 1/6400, 1/3200, 1/1600, 1/800, 1/400, 1/200, 1/100, 1/50rad. and 1/25rad. The out-of-plane deflections of specimens were confined by pantographs above the loading beam. Result and discuss Failure pattern Crack pattern in series-2 is shown Fig6. Spandrel type (No.2-1, No.2-2 and No.3-1): In very small load (shear force Q was from 10 to 40 kN), the crack occurred between the column and the cast-in-place spandrel which transferred the tensile stress. Next, flexural cracks of the columns, shear cracks of the columns and shear cracks of spandrels was observed in order. The compressive failure of spandrels, at connection of spandrel and column which transferred the compressive stress, occurred around 1/200rad. in story drift angle. The failure mode of the specimen No2-1 was the shear failure of column, and that of the specimen No.2-2 is the shear failure of column after the flexural yield of the column. In all column of the specimen No.3-1, the flexural yield of the column was observed. Sidewall type (No.3-2): In small load, the flexural crack of cast-in-place sidewalls was occurred the edge with the beams. The flexural crack of columns was observed around 1/1600rad. in story drift angle, and finally the column and the side-wall slid off (shear slip in connection of column and sidewalls) vertically. The failure mode was the flexural yield of the column.
No.3-1(R=+1/50[rad.])
No.3-2(R=+1/50[rad.])
Fig.6: Crack Pattern
No.2-1(R=+1/50[rad.])
No.2-2(R=+1/50[rad.])
Fig.7: Shear force(Q)-Displacement(δ ) relationship
◆Slip between Column and Sidewalls (SL) ●Yield of Main Bar in Column (Y) ■Shear Failure of a Column (S) ▲Compressive Failure of Spandrels (C) (L):Left Column (R):Right Column (C):Center column
1/100 1/50 1/25 R[rad.]
-1/100 -1/50
R[rad.]
-1/25
δ [mm]
10 20 30 40 50
-30 -20 -10 -40 -50
Q[kN]
300
200
100
-100
-200
-300
400
500
-400
-500
No.2-1
No.3-1
No.2-2
No.3-2
1/100 1/50 1/25 R[rad.]
-1/100 -1/50
R[rad.]
-1/25
δ [mm]
10 20 30 40 50
-30 -20 -10 -40 -50
Q[kN]
300
200
100
-100
-200
-300
1/100 1/50 1/25 R[rad.]
-1/100 -1/50
R[rad.]
-1/25
δ [mm]
10 20 30 40 50
-30 -20 -10 -40 -50
Q[kN]
300
200
100
-100
-200
-300
400
500
-400
-500
1/100 1/50 1/25 R[rad.]
-1/100 -1/50
R[rad.]
-1/25
δ [mm]
10 20 30 40 50
-30 -20 -10 -40 -50
Q[kN]
300
200
100
-100
-200
-300
Y(C,R)
C(R)
Y(R)
Y(L,C)
C(L,C)
C(C) C(R,L) Y(L)
S(L)
S(L)
S(R) C(L)
C(L) Y(R)
Y(L)
Y(R)
Y(L)
C(L)
S(L)
S(R)
Y(L,C,R)
SL(L)
SL(C) SL(R)
Y(L,C,R)
SL(C)
SL(R,L)
Frame Frame
Deformation properties Fig.7 shows the shear force (Q) – displacement ( δ ) relationship. Reduction in the stiffness was observed due to the flexural cracks of column and non-structural walls. In addition, reduction in the stiffness by slip of column and sidewalls was radical, and the shear force in case slip of column and sidewall became large as the thickness of sidewall became thick. After maximum load was observed, the shear force decreased due to the shear failure of column, the compressive failure of spandrel and the compressive failure of sidewalls. The decrease of shear force which was due to the compressive failure of cast-in-place non-structural walls (spandrels and sidewall) was Loosely. In the specimen No.3-1 and No.3-2, the shear force was rather higher than the flexural strength of the frame specimen, 2/3 times that of the specimen No.0-0. in story drift angle R=1/25 rad.. Fig.8 shows the skeleton curve of the shear force (Q) – displacement ( δ ) relationship, and the parameter in Fig.8 is the shear reinforcement of column (the specimen No.1-2, No.2-1 and No.2-2). Even if it is in case of the RC frame with cast-in-place non-structural walls, the failure mode changed from shear failure of column to the flexural yield of column by increasing the shear reinforcement of the column. Moreover, by increasing the shear reinforcement, the ductility was improved. Fig.9 shows the skeleton curve of the shear force (Q) – displacement ( δ ) relationship, and the parameter in Fig.9 is the thickness of spandrels (the specimen No.1-2 and No.2-1). The plus cycle and the minus cycle are shown in fig.9 to compare the thickness of the spandrels. The ductility of column with spandrel was improved as the spandrel became thin. The compressive failure of spandrel was observed, when the spandrel is thin, and the column with spandrel was changed from the short column to the long column by the compressive failure of spandrel. Therefore, it is important to develop the compressive failure of spandrel in order to obtain the ductility of column.
ANALYSIS (FINITE ELEMENT METHOD) The Finite Element Method (FEM) analysis, 2D non-liner, was conducted to clarify the shear resistant mechanism of the RC frame with cast-in-place non-structural RC wall, and to cover the test result.
0
100
200
300
400
0 10 20 30 40 50 60
0
100
200
300
400
0 10 20 30 40
Q[kN]
δ [mm]
R[rad.]
1/25 1/50 1/100 1/200
Q[kN]
δ [mm]
R[rad.]
1/50 1/100 1/200 1/400
No.2-2(pw=0.19%)
No.2-1(pw=0.38%)
No.1-2(pw=0.53%)
No.0-0(frame:
Shear Failure (t=40mm)
No.2-2 Plus cycle (t=40mm)
Shear Failure (t=80mm)
Shear Failure (t=40mm)
No.2-2 Minus cycle (t=80mm)
No.2-1 Minus cycle (t=80mm)
No.2-1 Plus cycle (t=40mm)
Fig.8: Shear force(Q)-Displacement(δ ) relationship skeleton curve(parameter: pw)
Fig.9: Shear force(Q)-Displacement(δ ) relationship skeleton curve(parameter: t)
Agreement between analysis and test Agreement between the analytical and the test was discussed. Outline of analytical method The mesh layouts of non-structural RC wall specimen are shown in Fig.10. The longitudinal bar in column was represented by line element, and shear reinforcing bars were arranged in two orthogonal directions and placed two layers in each direction. The bond between longitudinal bar and concrete was represented by bond link. In connection of members (columns, beams, and non-structural walls), the crack link was set for crack opening, and the dowel action of reinforcing bar was considered by dowel link. In this representation, the analysis result of the independent frame specimen (No.0-0) and the shear wall specimen showed good agreement with the test result [Sugiyama et al, 3]. Analytical Result Fig.11 show shear force (Q)-displacement ( δ ) relationships skeleton curve of analysis. Good agreement between the analysis and the test can be seen in crack propagation and progress of failure. Moreover, skeleton curve of Q- δ relationships by analysis agree with that of test result, and analytical result indicated that the decrease of stiffness was caused to failures of non-structural wall in the RC frame. In spandrel specimen, the capacity of analysis due to the flexural failure of column, the yield of longitudinal bar, was the same as the test result. However, in sidewall specimen, after slipping between the column and the sidewalls in the test, the Q- δ skeleton curve of analysis did not agree with that of test result. But, the analysis result shows the behavior of the RC frame with sidewall until slipping between the column and the sidewalls. Thus, analytical method is useful to clarify the shear resistant mechanism of a RC frame with cast-in-place non-structural RC walls. Parametric analysis Here, the parametric analysis was described. Outline of parametric analysis The parameters set in the analysis were thickness (t) of non-structural walls (spandrel and sidewall) or length (lw) of sidewalls. The mesh layout was same as shown in Fig.9. The thickness of non-structural in this analysis was varied from 0mm (Frame specimen) to 240mm (t/BC=1.0), and the length of sidewall in this analysis was varied from 0mm (Frame specimen) to 720mm (lw/DC=3.0).
Fig.10: Detail of mesh layout in FEM analysis (2D)
Link in two
(Line element)
Bond link Crack link
Crack link
Wall Column
Dowel link Crack link
Sidewall column
Beam
N/2 N/2
Q/2 Q/2
Stress is not transmitted
Spandrels
N/2 N/2
Q/2 Q/2
Beam
and Dowel link
directions
Longitudinal Bar
Analytical Result Fig.11 shows shear force (Q)-displacement ( δ ) relationships skeleton curve of analysis. Spandrel type specimen: In all specimen of analysis, the failure pattern was same, and the capacity was due to the flexural failure of column (the yield of the column). The initial stiffness of analysis became large as the spandrels became thick. The capacity also became large as the spandrel became thick, but the rise of capacity was leveling off if the thickness of spandrels was larger than 40mm. Sidewall type specimen: In all specimen of analysis, the failure pattern was same, and the compressive failure of sidewalls was observed. The initial stiffness and the maximum shear force became large as the sidewalls became thick. In the thickness of sidewall were 160mm and 240mm, the maximum shear force was due to the flexural failure of column. In case of others, the maximum shear force was due to the compressive failure of sidewalls. Therefore, in cases where the thickness of a sidewall was 160mm and 240mm, it is considered that the flexural failure was observed as the column and the sidewall was one member. State of stress Fig.12 shows the principal stress of the concrete element in analysis. In the spandrel type specimen, the
Fig.11: Analysis Result
0
50
100
150
200
250
300
350
400
0 2 4 6 8 10 12 14 16 18
1/400
D[m m]
1/200 R[rad.]
Fram e(Test:No.0-1)
Q[kN]
t=10m m
t=40m m
t=20m m
fram e
t=60m mt=80m mt=240m m
t=120m m
1/800
Test(No.1-2)
Fram e
t=10m m (1/24)
t=20m m (1/12)
t=40m m (1/6)
t=60m m (1/4)
t=80m m (1/3)
t=120m m (1/2)
t=240m m (1/1)
Spandrel-type Thic
-knesst
[mm]
Initial stiffness
K0
[kN/mm]
Max. force (Capacity)
Qmax
[kN] 10 111.5 280.4
12 115.5 288.5
16 120.5 291.8
20 124.1 302.7
30 134.6 315.1
40 141.7 323.2
60 154.4 326.1
80 162.6 332.1
100 169.5 318.5
120 175.1 322.9
160 183.3 331.2
240 191.8 331.3
Sidewall-type Thic
-kness
t
[mm]
Length
lw
[mm]
Initial
stiffness
K0
[kN/mm]
Max. force
(Capacity)
Qmax
[kN]
10 181.1 207.4
20 211.5 246.5
30 296.3 243.4
40 348.6 326.4
60 442.2 384.3
80 503.4 464.2
120 629.5 537.5
160 729.5 586.4
240
470
849.4 603.3
240 210.1 262.2 40
720 485.7 468.5
0
100
200
300
400
500
600
0 2 4 6 8 10 12 14
1/400
D[m m]
1/200 R[rad.]
Fram e(Test: No.0-0)
Q[kN]
t=240m m
Fram e(t=0m m )
1/800
Test(No.1-3)
1/100
t=120m m
t=80m m
t=60m m
t=40m m
t=20m m
t=10m m
Fram e
t=10m m (1/24)
t=20m m (1/12)
t=40m m (1/6)
t=60m m (1/4)
t=80m m (1/3)
t=120m m (1/2)
t=240m m (1/1)
0
100
200
300
400
500
0 2 4 6 8 10 12 14
1/400
D[m m]
1/200 R[rad.]
fram e(Test:No.0-0)
Q[kN]
lw=240m m
Fram e(t=0m m )
1/800
Test(No.1-3)
1/100
lw=470m m
lw=240m m
Fram e
lw=240m m (1.0)
lw=470m m (2.0)
lw=720m m (2.0)
compressive strut of concrete was observed in columns and spandrels, and the angle of the strut was changed by columns and strut. Thus, in order to evaluate the structural performance of the RC frame with the spandrel, the compressive stress of the spandrel should be considered. In the sidewall type specimen, the compressive strut of concrete existed in the diagonal line. Thus, in order to evaluate the structural performance of the RC frame with the sidewall, the stress transfer between column and sidewalls should be considered.
SHEAR RESISTANT OF COLUMN AND CAST-IN-PLACE NON-STRUCTURAL WALL The shear resistant, the state of stress in shear force, of the RC frame (column) and the cast-in-place non-structural RC walls was discussed from the test result and the analytical result. RC Frame with spandrel type non-structural walls Fig.13 shows an example of the moment distribution of the column in test and analysis. The moment of each section was calculated using the strain of longitudinal bar and the mechanical properties of steel and concrete. Although the moment of column was the linear distribution, it curves at the edge of the spandrel. Besides, the curvature becomes large as the spandrel becomes thick. Since the compression of spandrel was loaded to a pillar at the opposite direction of shear force, these states were observed. Fig.14 shows the distribution of compressive strain of the spandrel in the test and analysis, and the strain in test was measured on the surface of concrete. The strain of spandrel was the linear distribution, and the length of distribution was 1.0DC (depth of column). The length of distribution was constant without reference to the thickness of the spandrels. But, if the spandrel was compressive failure, the length became long. As described above, the place of combined compressive stress (C: compression of spandrel) is constant. Besides, since C (compression of spandrel) is small when the spandrel is thin, the shear span of column becomes long. RC Frame with sidewall type non-structural walls Fig.15 shows an example of the moment distribution of the column in test and analysis. In the exterior column (the column was connected to the sidewall at one side), the moment of column was a curved line-distribution so that the spandrel became thick. The same state was observed when the spandrel became long. On the other hand, in the interior column, the moment distribution of column was a linear distribution. Therefore, it is guessed that the compression of sidewall is uniformly loaded to the column. Fig.16 shows an example of the shear stress between the column and the sidewall in analysis. The distribution of shear stress was uniformly even if the sidewall thickness or length was changed. Fig.17 shows an example of the compressive strain of the sidewall in test. The strain was developed between the sidewall and the beam. Before the shear slip occurs in connection of the column and the
Fig.12: Principal stress of concrete in analysis
+Q
Compressive strut of concrete
+Q +Q
sidewall, the strain was linearly distributed including the column section. Therefore, the behavior of the column and the sidewall was one member. Then, after shear slipping in connection of the column and the sidewall, the compressive strain of sidewall is distributed from the edge only by the length of 1.0DC (depth of column). The strain was the linear distribution.
MODEL OF SHEAR RESISTANT MECHANISM AND ESTIMATE THE STRUCTURAL PERFORMANCE OF RC FRAME WITH CAST-IN-PLACE NON-STRUCTURAL WALLS
In this chapter, the method to estimate the structural performance of RC frame with cast-in-place nonstructural RC walls is proposed by the shear resistant mechanisms. Here, the shear force (Q) – displacement ( δ ) skeleton curve of RC frame with non-structural RC walls is evaluated. The Q- δ skeleton curve of the RC frame with non-structural walls was evaluated as a value which added all the Q-δ skeleton curve of the column with nonstructural walls.
5N/mm2 5N/mm2 5N/mm2 5N/mm2 t=40mm
lw=240mm t=40mm
lw=470mm t=80mm
lw=470 mm t=40mm
lw=720 mm
R=1/200rad. R=1/400rad. R=1/800rad. R=1/1600rad.
Sidewall Column
Sidewall Column Sidewall Column
Sidewall
Fig.16: Shear stress on connection
Column moment distribution
Mimetic diagram
QC
C
Resistant of wall
C<QC C>QC Analysis t=240mm
Analysis t=10mm
1/1600[rad.] 1/800[rad.] 1/400[rad.] 1/200[rad.] Qmax
Test (No.2-1) t=40mm
(Left Column :Plus cycle)
Test (No.2-1) t=80mm
(Right Column :Minus cycle)
Analysis t=40mm
Q Q Q Q -Q
DC/2
C MC
my (A
IJ)
Fig.13: Column moment distribution (in spandrel type)
0 0.10 0.20 Strain(-)[%]
Q Q Q -Q
Qmax
DC
0 0.10 0.20
Analysis t=240mm
Analysis t=10mm
Test (No.2-1) t=40mm
(Left Column :Plus cycle)
Test (No.2-1) t=80mm
(Right Column :Minus cycle)
0.208Column
Spandrel
0 0.10 0.20
Qmax
0 0.10 0.20 Strain(-)[%] Strain(-)[%] Strain(-)[%]
Qmax
0.208 0.208 0.208
Fig.14: Strain distribution of spandrel
Column
Analysis t=20mm lw=470mm
Test (No.3-2) Left column (+Q) t=60mm lw=240m
Test (No.3-2) Right Column (-Q) t=40mm lw=240mm
Analysis t=80mm lw=470mm
C MC
my (A
IJ)
Analysis t=40mm lw=470mm
Analysis t=40mm lw=720mm
1/800[rad.] 1/1600[rad.]
1/400[rad.] 1/200[rad.] Qmax
1/3200[rad.]
Q
Resistant of wall
QC
Q
QC Resistant of wall (left)
Test (No.3-2) Center column (+Q) t=40mm lw=360m
Resistant of wall (Right)
Test (No.1-2) Left column (+Q) t=40mm lw=470m
Fig.15: Column moment distribution (in sidewall type)
DC(Depth of column) DC(Depth of column)
-3000
-2500
-2000
-1500
-1000
-500
0
500
ε[μ] - 1/800[rad.] 1/800-1/400[rad.] 1/400-1/200[rad.]
Q
t =60mm
Q
t =40mm
Fig.17: Compressive stress of sidewall (in test)
Model Fig.18 shows the model of the Q- δ skeleton curve of the column with nonstructural walls. The Q- δ skeleton curve of the column with nonstructural walls is evaluated by bi-linear in the range until the flexural failure of column. However, in cases where the shear slip occurs in the connection of column and sidewall, the Q- δ skeleton curve of the column with sidewalls is evaluated by tri-linear in the range until the flexural failure of column. As shown in a fig.18 evaluation matters are K1 (Initial stiffness), Ky (Stiffness at flexural yield), Qmcr (Flexural crack strength), Qmy (Flexural capacity), Qsu (Shear strength), Qslip (Slip strength) and uδ (Ultimate displacement). Moreover, if the nonstructural walls fails (compressive failure of spandrel or/and shear slipping of column and spandrels), it is evaluated that the behavior of column with the non-structural walls shifted to the behavior of independent column. Fig.19 shows the model of the shear resistant mechanism. The model is as follows. Spandrel type: The compressive stress of triangle distribution is developed in the spandrels. The combined compressive stress exists in the position of DC/3 from the end of the spandrels. Sidewall type: The stress in the connection of column and sidewall is distributed uniformly. Before the shear slip occurs in the connection of column and sidewall, the behavior of the column and the sidewall was one member. Then, after shear slipping in the connection of column and sidewall, the compressive stress of sidewall is distributed from the edge only by the length of 1.0DC (depth of column). Moreover, the distribution is liner. Evaluation of the shear-displacement relationship of RC columns with the non-structural walls Table 3 shows the equations to estimate the shear-displacement skeleton curve of RC columns with non-structural walls. The equations were evaluated from the shear resistant mechanism.
(e)Resistant mechanism of Sidewall Type
TCC TCWc
DC
BCWc
TTWs
BCC
TTCs
BTCs
τ C-W
σ C-W
τ C-W
σ C-W
BTWs
DC
DC
lw lw
σ st
BCWc
TTWs
BCC
TCC TTCs
BTCs
τ C-W
σ C-W
τ C-W
σ C-W
TCWc
BTWs
h0'
lw lw
τ C-W
Sliping on connection
σ C-W
θ s
MWT MCT
M1
M2=
- α M1
Crack DC
θ st
I
W
Q M2=- α M1
M1
MCB MWB
Crack
DC
W
I
θ st
Q
(d)Resistant mechanism of Spandrel Type
Shear Moment
MWT
M2=
- α M1
M1
MCB MWB
MCT
x=DC
Crack
Ck
Ct x=DC
DC Crack
Q
Ck=-β kQC
QC
Ct=-β tQC
QCk
QCt
h0’
hk’
xk
hk
h0
ht
xt
ht’
h
(a)Q-δ of Spandrel Type
δ Cu δ CW1u
KCW1-1
δ CW1y
QCW1my
QCW1mcr
KCW1y
QCmy
(h0’=h)
QC
δ CW1u< δ Cu
(QCsu)
QCW1my>Cc
δ Cu=Rph
(b)Q-δ of Sidewall type (not slip)
δ
KCW1-2
δ CW2y δ Cu
QCW2my
QCW2mcr
KCW2y
QCmy
QC
δ CW2u
δ CW1u< δ Cu
KCW1-2
KCy
δ Cy δ Cu
δ
QCW2my
Qslip
QCW2mcr
KCW2y
QCW2slmy
QCmy
QC
δ Cu=Rph
(c)Q-δ of Sidewall type (slip)
Fig.18: Model to estimate the structural performance (Q-δ ) of RC frame with non-structural walls
Initial stiffness (K1) The initial stiffness is evaluated in consideration of the flexural deformation ( mδ ) and the shear
deformation ( sδ ) (Eq.(1), Eq.(2) and Eq.(3)). The initial stiffness of a column with the spandrels is given by Eq.(4-1) and eq.(5-1) from fig.18(d). The β ( kβ and tβ ) is the ratio of the compression of spandrel (C) to the shear force of column. The β ( kβ and tβ ) is evaluated in consideration of the stiffness of column and that of spandrel, and is calculated by Eq.(6) and Eq.(7). The initial stiffness of a column with the sidewall is calculated by Eq.(4-2) and Eq.(5-2), the section modulus is calculated by the equation in consideration of cross-sectional shape (ZW and AW) [Okubo, 4]. Stiffness at flexural yield (K2) The stiffness at flexural yield is calculated by Eq.(8), Eq.(9) and Eq.(10) using the standard of AIJ[5] Flexural crack strength (Qmcr) The flexural crack strength of the column with the spandrel is calculated by Eq.(11-1) and Eq.(12-1) using the standard of AIJ[5]. Similar, The flexural crack strength of the column with the sidewall is calculated by Eq.(11-2) and eq.(12-2). Capacities (Flexural Capacity, Shear Strength, Failure Strength of spandrel and Slip strength) Flexural capacity: The flexural capacity of independent column (QCmy) is calculated by Eq. (13-1) and eq.(14) using the flexural capacity equation of AIJ [5]. The flexural capacity of column with spandrels (QCW1my) is given by eq. (14-1) in consideration of the shear span. If the column and the sidewall are one member, the flexural capacity of column with sidewall is calculated by Eq. (14-2) and eq.(14-2)’ using the flexural capacity equation [Masuo et al., 6]. Then, after shear slipping in the connection of column and sidewall, the flexural capacity of column with sidewall is given by Eq. (14-3) and eq.(14-3)’ from fig.18(e) Shear strength: The shear strength of independent column (QCmy) is calculated by Eq. (15) using the shear strength equation of AIJ [7]. If the column and the sidewall are one member, the calculation of shear strength of column with sidewall is used the shear strength equation [Masuo et al., 6]. In the case of others, the shear strength of the column is calculated by Eq. (15). Compressive failure strength of spandrel: Since compressive stress distribution of spandrel is assumed to be a triangle from Fig. 18(d), the compressive failure strength of spandrel is given by Eq.(16). Slip strength: When a crack occurs on the connection of column and sidewalls, it is assumed that the column and the spandrel is slip. Therefore, the shear stress in case the column and the spandrel slip is given by Eq. (17) from Fig. 18(e). And in consideration of the compressive stress of sidewall (Cwc), slip strength (Qslip) is given by Eq.18. Failure mode Failure mode is classified into the flexural yield of column, if the shear strength of column is lower than the flexural capacity of column. In the column with spandrel, if the compressive failure strength of spandrel (Cc) is lower than the flexural capacity of column (QCW1my), the compressive failure of spandrel occurs. In the column with sidewall, if slip strength (Qslip) is lower than the flexural capacity of column (QCW2my), the slipping in connection of column and sidewall occurs. ductility The displacement in case the flexural capacity of column and the shear strength of column, which were reduced by the plastic angle of column (Rp), become equal is estimated as the ultimate displacement ( uδ ).
The ultimate displacement ( uδ ) is given Eq.19 from fig.18.
E: Elastic modulus of concrete, G: shear modulus of concrete, I: Moment of inertia of column, A: Cross-section area of column, IW: Moment of inertia of sidewall column with sidewall, AW: Cross-section area of column with sidewall, n: Elastic modulus ratio of steel to concrete, ht,hk: Height of spandrels h: Height of column t: thickness of wall, lw: length of sidewall pt: Ratio of tensile longitudinal bar to section, DC: Depth of column, BC: Width of column, NC: Axial force of column, σ B: Compressive strength of concrete, σ t: Tensile strength of concrete, σ y: Yield strength of longitudinal bar of column, σ wy: Yield strength of shear reinforcement of column, pw: Ratio of shear reinforcement of column, ps: Ratio of reinforcement of wall,
Table3: the equations to estimate the shear-displacement skeleton curve
{ } )2()(
)(1 ∫∫∫∫
=ϕ=δ dydy
EI
yMdydyy C
m )3(1 ∫
κ=δ dy
GA
QCs
)1(11
1sm
CQK
δ+δ=
)24(12
'3021 −=δ −
W
CCWm EI
hQ
)25('0
1 −κ=δW
CWCWs GA
hQ
{{ } { }} )14()''(')''('3
')1('1
13)1(
61
30
320
2
20
311
−+β−β++β+β−+
β−+
β−α+
+β−−=δ −
Cktkkktkk
ktttCWm
Qhhhhhhh
hhhhEI
{ } )15(')1('')1( 011 −β−++β−κ=δ − CttkkCWs QhhhGA
)6(cos
''
3
'
cos
'
)1(2
''00.1
32
θκ
θ−
α++β
st
kkk
st
kk0k tWE
h
GA
h
EI
h
tWE
h
EI
hh++=
)7(cos
''
3
'
cos
'
)1(2
''00.1
32
θκ
θ−
α+α+β
st
ttt
st
tt0t tWE
h
GA
h
EI
h
tWE
h
EI
hh++=
)10(0.130.461p Bwywu +σσ=β( )( ) )9(/ 2
0 CCt Dd0.325Da0.04341.635np0.0432 η+=α ++y)8(
11 usym
C
symy
Cy
QQK
βδ+αδ=
δ+δ=
)111(6/56.0 −+σ= CCBCmcr DNZM
( ) )112()1()1()1(1 −β++βα+ 'h-'h'h-MQ tt0kkCmcrmcrCW =
Z=BCDC2/6 )211(656.02 −+σ= /DNZM WCWBmcrCW
)212(2 022 −=
CC'hMQ mcrWmcrW
)15(2/)1(tancot BCCywwtCsu DBpjcBQ νσβ−θ+φσ=
)0.1)/()tan(0.2mincot σνσ,θ, φ −= ywwBt pcD/j(
)113())(1(5.08.0 −−+= σσC BCCCCCCysmy DBNDNDaM
ννp 0)150.1( R−=
cD
hcDh ''tan 0
220 −+
=θ
2007.00
Bσ−=ν=ν
( ) )114()1()1(21 −β++β 'h-'h'h-MQ tt0kkCmymyCW =
)16(2/Bc ctDC σ=
)19(hRpCpCyCu +δ=δ+δ=δ Cy
QCW2slmy=2MCW2slmy/h0’ (Interior column) (14-3) QCW2slmy=(MCW2slmy+MCmy)/h0’ (Outer column) (14-3)’
( ) CwWcBCCC
CCCytCWslmy
DCDBN
DNDaM
β))σ(Δ (
Δσ=
++−
+
6/11
5.08.0
( )3/22/1
5.08.0
wCWcBCCC
CCCytCWslmy
lDCDBN
DNDaM
++−
+
))σ(Δ (
Δσ=
0 ≤ βw ≤ 2 NC ≤ 0.4BCDC σ B ∆ NC=NC-CWc CWc=tDC σ B/2 (DC ≤ lw) CWc=tlw σ B/2 (DC>lw)
)17(2/)4tan(tan 2tss σ+θ+θ=0
2 σσ+σ=τ ・ttsl
Qslip=(CWc(sl)/ CWc(my))QCW2my (18) CWc(sl) =τslh0't CWc(my)=min(0.85σBtlw,at σ y+an σ y+NC)
If it calculates simple α =1.0,
W=DC 45=θst degrees
QClmy=2MCWlmy/h (14)
QCW2my=2MCW2my/h0’ (Interior column) (14-2) QCW2my=(MCW2my+MCmy)/h0’ (Outer column) (14-2)’ MCW2my=Mu1, Mu2, Mu3, Mu4, Mu5
Nwu= η ctlw σ B
Mwu=Nwu・(DC+lw)/2 η c=0.85 Nws=aw σ sy (=tlwps) Mwu=Nwu・(DC+lw)/2 Mws=2Nws(DC+lw)/2 N5 ≥ NC>N4
Mu1=(0.8at σ yDC+0.12BCDC2 σ B+Mwu+Mws)
(N’max+anσy+2Nwu+2Nws-NC) /( N’max-0.4BCDC σ B+Nwu+2Nws)
N4 ≥ NC>N3
Mu2=0.8at σ yDC+0.12BCDC2 σ B+Mwu+Mws
N3 ≥ NC>N2 Mu3=(0.8at σ yDC+0.5(NC + an σ y-Nwu) DC {1-(NC + an σ y-Nwu)/(BCDC σ B)}+ Mwu+Mws
N2 ≥ NC>N1 Mu4=0.8at σ yDC[1-(NC + an σ y-Nwu)/N’min]+ Mwu+Mws
N1 ≥ NC>N0 Mu5=(Mwu+Mws)(NC-N’min + an σ y+2Nws)/(Nwu+2Nws)
wsyn NaNN 2'min0 −−= ・σ wuyn NaNN +−= ・σmin1 '
wuyn NaN +−= ・σ2
wuynBCC NaDBN ++= ・σσ4.04
wuynBCC NaDBN +−= ・σσ4.03
ytBCC aDBN σ2'max +σ=ytaN ・σ2'min −=
wswuyn NNaNN 22'max5 +++= ・σ
B
ywwp
νσ
σφ )cot1( 2+=β
(DC ≤ Lw)
(DC<Lw)
Agreement of proposed method to the test and the analysis Fig.19 shows an example of the calculated value in comparison with the test result and the analysis result. Good agreement between the calculation and the test can be seen in the stiffness, the decrease of stiffness, capacities and the decrease of flexural capacity. Similarly, the calculation result is in agreement with the analysis result. Also, the failure mode of column and non-structural wall was appropriately judged, so, the proposed method can evaluate the structural performance of the RC frame with cast-in-place non-structural wall.
CONCLUSION The conclusions of this paper are below; 1) If the column has the shear reinforcement which can resist the shear force, the structural performance
(stiffness, capacity and energy dissipation) of the RC frame with cast-in-place non-structural RC walls (spandrels and sidewalls) is advanced from that of the open RC frame.
2) From tests and FEM analysis, the influence to the structural performance of RC frame of principal factor, the shear reinforcement of the column and the shape of the cast-in-place non-structural RC wall, were suggested.
3) The shear resistant mechanism of the RC frames (columns) and the non-structural RC walls was clarified with test results and analytical results.
4) By the shear resistant mechanisms, this paper proposed the method to predict the structural performance (the load-displacement relationship) of RC frames with non-structural RC walls.
0
100
200
300
400
500
600
0 10 20 30 40
1/100 1/501/2000
100
200
300
400
500
600
0 10 20 30 40
1/100 1/501/200
No.3-1 Spandrels No.3-2 Side-walls
R[rad.] R[rad.]
δ [mm] δ [mm]
Right
Left column Center column
Right
Left column
Center column
Frame
test
Frame
test
Q[kN] Q[kN]
Fig.19: Compared the calculated value with the test and/or the FEM analysis
0
100
200
300
400
500
600
700
0
200
400
600
800
1000
1200
150
200
250
300
350
400
0
50
100
150
200
250
6 1
5 1
4 1
3 1
2 1
BC t
6 1
5 1
4 1
3 1
2 1
BC t
No.2-1
Initial stiffness Flexural capasity
No.1-3
No.2-2
Test Analysis
Calculation
No.0-0
No.2-1 No.1-3
No.0-0
Qy[kN] K1[kN/mm] K1 [kN/mm]
t/BC 1 6
1 4
1 3
1 2
2 3
t/BC 1 6
1 4
1 3
1 2
2 3
Q [kN/mm]
cQCW2my Analysis Test
cQCW2slm
cQslip
Yield of main bar
Test Analysis
Calculation
Test Analysis
Calculation
Initial stiffness Maximum shear force Initial stiffness Maximum shear force
REFERENCES
1. Architectural Institute of Japan “Report on the Hanshin-Awaji Earthquake Disaster, Building Series
Volume, Structural Damage to Reinforced Concrete Building” 1997 2. Architectural Institute of Japan “Recommendation to RC Structural Design after Hanshin-Awaji
Earthquake Disaster -Cause of particularly noticed damages and corresponding RC structural design details-“ 1998 (in Japanese)
3. Sugiyama, T., Uemura, M., Fukuyama, H., Nakano, H., Matsuzaki, Y. “Experimental study on the performance of the RC frame infilled cast-in-place non-structural RC walls retrofitted by using carbon fiber sheets” Proceedings of the 12th WCEE, Paper no.2153,2000
4. Okubo, “Experimental study on the behavior of Reinforced beam with spandrels (part 2)” Transactions of the Architectural Institute of Japan, No.207, May 1973: 9-17
5. Architectural Institute of Japan ”Standard for Structural Calculation of Reinforced Concrete Structures -Based on Allowable Stress Concept-“ 1999 (in Japanese)
6. Masuo, K., Jinno, Y. ”Improving effects on ultimate strength and ductility of R/C columns with wing walls by wrapping of CFRP sheets around column” Journal of structural and construction engineering (Transaction Architectural Institute of Japan), No536, Oct 2000: 121-128
7. Architectural Institute of Japan “Design Guideline for Earthquake Resistant Reinforced Concrete Buildings Based on Ultimate Strength Concept” 1990 (in Japanese)