Gravity Load Collapse Behavior of Nonengineered Reinforced Concrete Columns

)is paper aims at investigating gravity load collapse behavior of extremely poor quality reinforced concrete columns under cyclic loading. Such columns were usually constructed by local people and may not be designed to meet any of the standards. It was found that their concrete strength may be as low as 5MPa and the amount of longitudinal reinforcement may be lower than 1%. )is type of column is deliberately defined as “nonengineered reinforced concrete column,” or NRCC. During earthquake, the gravity load collapse of the NRCC columns caused a large number of death tolls around the world. In this study, four columns as representative of existing NRCC were tested under cyclic loading. )e compressive strength of concrete in order of 5MPa was used to be representative of columns with poor quality concrete. Two axial load levels of 6 and 18 tons were used to study the influence of axial load level on maximum drift at gravity load collapse. To investigate the effect of bar types on drift capacity, 9mm round bars were used in two specimens and 12mm deformed bars were used for the rest of the specimens. )e maximum drift before gravity load collapse was very dependent on the axial load level. )e maximum drift of the specimens subjected to high axial load (18 tons) was extremely low at approximately 1.75% drifts. )e use of deformed bars (associated with larger amount of longitudinal reinforcement) caused the damage to severely dissipate all over the height of the columns. Such damage caused columns to collapse at a lower drift compared to those using round bars. Finally, the plastic hinge model was used to predict the maximum drift of the low strength columns. It was found that the model overly underestimates the drift at gravity load collapse.


Introduction
During several past decades, earthquake engineering research has been undertaken to better understanding structural behavior under severe earthquake.To prevent structural damage or collapse under strong seismic excitation, the structural design using ductile detailing of RC structures has been investigated [1][2][3][4][5].For existing or old building, many strengthening approaches such as wrapping structures using carbon fiber reinforced polymer (CFRP) [6][7][8][9][10][11], steel jacketing, and buckling restrained bracing (BRB) have been developed [12][13][14][15].Most design methods and strengthening techniques developed in the past decades were found to be very effective and experimentally proved to be able to prevent the building collapse from strong earthquake [16].If the findings from earthquake research and development could be practically applied, the number of death tolls from earthquake around the world should be significantly reduced.However, during the recent earthquake such as Sichuan earthquake in 2008 [17] and Haiti earthquake in 2010, the total number of death toll was more than 200,000 [18].e collapse of buildings is shown in Figure 1.
A large number of death from earthquake implied that the current earthquake engineering knowledge is not effectively applicable for the structures in these regions [19].e structures in these regions were found to be poorly constructed and not conformed to any design standard as shown in Figure 2. e structure constructed by local people using material or reinforcement detailed below the design standard may be classified as "nonengineered structures."In this study, the columns are of most interest.is type of column is defined as "nonengineered reinforced concrete column," or NRCC.ese structures are very vulnerable to the earthquake.Significantly, there are very limited numbers of research on seismic behavior of such structures under the earthquake.
e construction cost of these structures is extremely low, and hence any available strengthening methods are considered too expensive to be practically used for retrofitting these structures.[20].(b) Poor quality concrete in Sichuan [21].(c) Collapsed column with inadequate lap splice length and widely spaced transverse bars in Gujarat, India [22].(d) Poor reinforcement detailing in Chiang Rai [23].

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To economically and effectively retrofit these structures, the behavior of the structures under earthquake should be studied prior to develop a proper strengthening approach [24].
erefore, in this study, the behavior of four column specimens as representative of nonengineered columns, or NRCC, was tested to investigate their seismic behavior.e gravity load-carrying mechanism and collapse behavior are of most interest.e test setup and test results will be discussed in the next sections.

Experimental Program
2.1.Test Specimen.Four column specimens (12L-0.2,12L-0.6,9L-0.2, and 9L-0.6) as representative of prototype columns with low strength concrete in order of 5 MPa were tested under cyclic loading.It is noted that to control mix proportion of low concrete strength to be exactly 5 MPa is very difficult.erefore, concrete strength in the test date may vary from 3.8 to 5.4 MPa.
e summaries of mix properties for concrete are shown in Table 1.All specimens were 200 × 300 mm in cross section with the height of 1250 mm.To study the effect of bar size on their seismic behavior, 4-DB12 was used as longitudinal reinforcement of two columns whilst 4-RB9 was used for the rest.e transverse reinforcement ratio of all specimens is very low around 0.1%.e 90 °hook as shown in Figure 3 was used in all specimens.e longitudinal bar yield strength is about 470 MPa and 354 MPa for DB12 and RB9, respectively.For stirrup, the yield strength is 511 MPa. e properties of test specimens including reinforcement detailing are shown in Table 2.

Test Setup.
e axial load was applied and maintained using a hydraulic jack, whilst the lateral load was applied using an actuator with 50 kN loading capacity.
e displacement controlled pattern as shown in Figure 4(b) was used in this test.e column will be pushed to the target drift twice to assure that the hysteretic loop is stable before increasing drift to subsequent cycle.e test setup is shown in Figure 4(a).e drift ratio of low strength concrete columns is made up of flexural, yield penetration, and shear components which can be measured using strain gauges and linear variable displacement transducer (LVDT).Twelve strain gauges were installed on the reinforcement to measure the longitudinal and transverse strains.e discussion on all sensors' measurement is currently under preparation and will be further reported in the future.e highlighted topic in this paper is the gravity load-carrying capacity of these NRCC columns.e axial collapse behavior of these columns is of most interest since this will significantly affect loss of life.erefore, the test frame as shown in Figure 4(a) was specially designed to be able to maintain the axial load during the test.e test was not terminated when the lateral resistance dropped by 20% of the maximum lateral force as typical cyclic load test.e test was performed beyond this point and terminated only when the axial load cannot be maintained.In this test, axial displacement at the tip of the columns was measured using LVDT in order that axial shortening behavior before gravity load collapse could be monitored.

e Lateral Drifts at 1.5%.
e crack patterns at 1.5% drift of all column specimens are shown in Figure 5. e pattern of crack in all columns was very similar and found to be initiated by flexural crack.e cracks propagated and changed to shear crack pattern near the centerline of the columns.It was evidently found that the cracks were widely spread up to 500 mm from the base of the columns using DB12 longitudinal reinforcement (12L-0.2and 12L-0.6).However, for columns using RB9 (9L-0.2 and 9L-0.6), the cracks were limited near the base area.erefore, it can be concluded that the crack locations are related to the types of longitudinal reinforcement.e use of deformed bars as longitudinal reinforcement in NRCC may cause widespread of crack along the column height.In contrast, the cracks seem to be limited in the plastic hinge location when round bars were used.e axial load levels also have significant influence on the crack pattern.From Figure 5, the cover spalling was observed in the high axial load columns (9L-0.6 and 12L-0.6).e concrete cover spalling in the first few cycles may cause the longitudinal bar buckle leading to column collapse at a very low drift.Advances in Civil Engineering 3

e Lateral Drifts at
Collapse.After 1.5% drift, the test has been carried on, and the lateral drift of all columns increased to the next target drifts until the collapse stage.In this study, the collapse is de ned as the drift at which the column could not sustain its gravity load.When the drift increased, the existing cracks were propagated to the center, and the cracks have increased size and length.Figure 6 shows the crack pattern at collapse and failure mode of all the tested columns.e first pattern is concrete splitting along the column height as observed in the failure mode of the columns 12L-0.2 and 12L-0.6,as illustrated in Figures 6(a) and 6(b).In these columns, the inclined shear cracks were initiated due to the larger applied maximum shear force (compared to those in 9L-0.2 and 9L-0.6)associated with larger amount of longitudinal bars.After shear cracking, the longitudinal bars buckling was observed.Eventually, the column lost its integrity and collapse under gravity load at the drift of 4% and 1.75% for column 12L-0.2 and 12L-0.6,respectively.e second pattern is concrete crushing within the plastic hinge region as observed in the failure mode of the column 9L-0.2 and 9L-0.6, as illustrated in Figures 6(c) and 6(d).In these columns, the flexural cracks were initiated near the column base.e cracks did not propagate through the height of the column but were confined to the plastic hinge area.Eventually, concrete splitting and bar buckling were limited only in the plastic hinge area.e gravity load collapse at the drift of 3.5% and 1.75% for column 9L-0.2 and 9L-0.6,respectively.It was found that the crack pattern and location mainly depend on the type of longitudinal reinforcement.
When DB12 bars were used as a longitudinal reinforcement, the crack size was very large and dissipated all over the columns.In contrast, when the round bars were used, the cracks were limited to only in the plastic hinge location.Although the crack patterns of the columns using the same bar type are similar, the maximum drifts at failure of the columns are significantly different.e high axial load columns (9L-0.6 and 12L-0.6)collapsed under gravity load only at a drift of 1.75%.For columns subjected to lower axial load, the drift at collapse of the columns using round bars (9L-0.2) was 4% but 3.5% drift for the column using deformed bars (12L-0.2).When the deformed bars were used, the column could tolerate lateral displacement slightly less than that using round bar providing that the axial load level was low.It is evident that the drift at axial load collapse of NRCC columns is significantly dependent on axial load level but slightly dependent on type of longitudinal reinforcement.
e type of longitudinal reinforcements plays more important role on drift level only when the axial load level is low.e use of round bars in NRCC is recommended since it could lead to columns collapse under gravity load at larger drift compared to those using deformed bar.Advances in Civil Engineering

Lateral Load-Drift Ratio Responses
Figure 7 shows the relationship between lateral load and drift ratio (including displacement) of all the test specimens.e lateral force was measured using load cell attached to the actuator arm.e displacement of the columns was measured using LVDT to monitor movement at the column tip.e measured displacement was used to calculate drift ratio by dividing column shear span (1.25 m). e lateral load was then plotted against drift ratio as shown in Figure 7.
During the low drift cycle (less than 0.5%), the hysteresis loop of all columns was very stable, and the linear relationship between force and displacement was observed in the ascending curve in the first and second cycle.is can be implied that the column behavior under cyclic loading in a very low drift is in the elastic range.When the drift cycle increases, the second hysteretic loop shows peak loop strength degradation.Furthermore, it was observed that when the deformed bars were used (12L-0.6 and 12L-0.2),there was a significant lateral peak strength drop in the second cycle.Much less second cycle strength drop was observed in the columns using round bars (9L-0.2 and 9L-0.6).e effect of axial load level on cyclic behavior of NRCC is also very important.e columns 12L-0.2 and 9L-0.2 that were subjected to low axial load could tolerate larger number of cycles compared to those subjected to high axial load (12L-0.6 and 9L-0.6).erefore, the energy dissipation of these low axial load columns was higher than the counterparts as shown in Figure 7. e use of different bar types also influenced the shape of hysteretic loop.e loop was narrow when the deformed bars were used compared to those using round bars.Consequently, the energy dissipation of the columns using deformed bars was lower than those using round bars providing that the axial load ratios were equal.

The Envelope Curves of All Specimens
To compare the overall force and drift behavior under cyclic loading of all specimens, the envelop curves of lateral loaddrift relationship of all specimens were plotted as shown in Figure 8.All specimens showed the elastic behavior under low level of lateral force.In term of lateral resistance, the maximum resistance was obtained when 12 mm deformed bars were used (12L-0.2) under low axial load level.However, with the same deformed bars, higher axial load level (12L-0.6)6 Advances in Civil Engineering decreased the column lateral resistance. is is due to the compression failure of low strength concrete associated with concrete crushing before longitudinal reinforcement developing their full tensile strength.When concrete crushing in the column subjected to high axial load level, the axial collapse occurred at a very low drift of 1.75%.e use of round bars in the low axial load column (9L-0.2) signi cantly in uenced on lateral load resistance capacity.e lateral resistance of the low axial load columns was signi cantly dependent on and proportional to amount of longitudinal reinforcement.e lateral resistance of columns under low axial load level was evidently controlled by tensile resistance of steel since tension failure mode is controlled overall behavior of such columns.However, the use of round bars seems to slightly bene t the column drift capacity.For example, the column 9L-0.2 has a larger drift at collapse than the column 12L-0.2.For columns under high axial load ratio, the envelop curves of both columns (12L-0.6 and 9L-0.2) including drift capacity at collapse were not signi cantly di erent as shown in Figure 8. is is due to the fact that the overall behavior is controlled by compression failure as previously discussed.e column test results are summarized in Table 3.In the case of axial load level at 6 ton, the maximum lateral load of specimens 12L-0.2 was 23.25 kN. is lateral load was significantly higher than that of specimen 9L-0.2 (13.8 kN).On the other hand, the drift at failure of specimens 12L-0.2 is 3.5%.is lateral load was lower than that of specimen 9L-0.2 (4% drift).In this case, the maximum lateral resistant of the columns with longitudinal reinforcement ratio 0.75 was higher than that of 0.31.In contrast, the drift at failure of the column with longitudinal reinforcement ratio 0.75 was lower than that of 0.31.
When the axial load level increased to 18 ton, the maximum lateral load and drift at failure for both specimens 12L-0.6 and 9L-0.6 were rather similar, as shown in Table 3.
e test results indicated that the axial load ratio a ects maximum lateral load and drift capacity of all columns.Advances in Civil Engineering

Axial Displacement and Drift Ratio Relationship
Figure 9 shows the relationship between axial deformation and lateral displacement of the NRCC columns under cyclic loading.During the cyclic load test, the axial load level was kept constant throughout the test, and the axial displacement was carefully monitored using a displacement transducer mounted at the top of the columns.From Figure 9, during the first few cycles, there was no significant axial shorting of all test columns.When the lateral drift was increased and the column cracking and concrete cover spalling were evidently observed, the axial shortening had started to increase.It was observed that before the peak resistance (as marked by (1) in Figure 9), there was almost no axial shortening.However, after peak load or postpeak regions, the axial shortening had initiated and sharply increased after point (2) as shown in Figure 9.When the second cyclic loop was applied, the axial shortening has continuously increased, and hence, this point was deemed the gravity load collapse.e drifts at this stage of all test columns were recorded and are summarized in Table 3. is drift axial load collapse is the most realistic collapse point that can be used to justify the maximum drift of NRCC columns.e influence of various parameters on gravity load collapse mechanism of NRCC columns has also been studied.For the column 12L-0.2, the largest amount of longitudinal reinforcement and lowest axial force were used.It was found that that axial shortening occurred at a very high drift (almost 3%).However, once the axial shortening has been initiated, gravity load collapse occurred soon after this point (3.5% drift).e initiation of axial shortening at high drift compared to other columns because the longitudinal reinforcements have a significant contribution to carrying the axial load (at low level).However, when the concrete cover was spalling at high drift, the bars were not effectively confined by concrete cover.Eventually, load-carrying capacity of the bars has been lost due to compression buckling followed by sharply axial shortening, leading to gravity load collapse of the column.
For the column 12L-0.6, the axial load level was increased and consequently, higher axial stress has imposed on both concrete and longitudinal bars.
e axial shortening has initiated soon after the peak lateral load.e sharp increase in axial displacement occurred when the number of cycle increased.Concrete crushing following by bars buckle at a very low drift caused the rapid column shortening following gravity load collapse of the column.When longitudinal reinforcement ratio was reduced approximately 50% (columns 9L-0.2 and 9L-0.6),axial load-carrying capacity contributed by longitudinal reinforcement was therefore reduced approximately 50%.In this case, the more proportion of axial load will be transferred to concrete compared to the columns using 4 db (12 bars).Hence, the shortening behavior was likely to be controlled by behavior of concrete under compression.
e axial shortening has initiated soon after the peak lateral resistance and continuously increased until gravity load collapse was imminent.It was also found that when the level of axial load was high such as in the column 9L-0.6, the axial deformation increased rapidly when the number of cycle and drift increased.

Theoretical Model for Column Collapse
In this section, the numerical framework is proposed to predict the behavior of low strength concrete columns by plastic hinge concept such as the well-known Paulay model in 1923.e model could provide a conservative estimate when used for evaluating seismic resistance of reinforced concrete structures [25].e model was used to predict the maximum lateral load and ultimate drift ratio, as shown in Table 4. Comparison has been made between prediction results and test result for all specimens.
Ductility of reinforced concrete column (μ Δ ) can be calculated from the Paulay model in 1923 [26]: where Δ m � Δ y + Δ p , Δ m is the maximum displacement (mm), Δ y is the yield displacement (mm), and Δ p is the plastic displacement (mm).e yield displacement (Δ y ) of cantilever may be estimated as follows: where ϕ y is the yield curvature (rad/mm) and l is the length of column (mm).From Figure 10, the yield curvature (ϕ y ) is given by ϕ y M i /M i ′ϕ i ′ an acceptable approximation for beam sections to calculate the steel and concrete extreme ber strain, and hence curvature ϕ y ′, based on conventional elastic section analysis at a moment of M i ′ 0.75M i thus providing an equivalent yield curvature of ϕ y 1.33ϕ y ′, when where ε y is the yield strain of longitudinal reinforcements, c is the distance between the top the compressive section and the neutral axis NA (mm), and d is the e ective depth (mm).From Figure 11, assuming that the plastic rotation to be concentrated at the mid-height of the plastic hinge, thus, the plastic displacement at cantilever tip is where ϕ m is the maximum curvature (rad/mm), ϕ p is the plastic hinge curvature (rad/mm), and l p is plastic hinge length of the column (mm).e maximum curvature (ϕ m ) is given by (1) Peak shear strength (2) Gravity load collapse

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where C u is the distance between the top of the compressive section and the neutral axis NA at the maximum curvature (mm).e plastic hinge length of column (l p ) can be estimated as where h is the section depth (mm).

Numerical Simulation
e prediction of the maximum lateral strength and ultimate drift of all test columns are shown in Table 4 along with the results from the experiment.e prediction of maximum lateral strength was calculated by simply applying the concept of plane stress remaining plain after bending.e material models used in this calculation (concrete and longitudinal reinforcement) were calibrated against material testing results.It was found that the predictions provide slightly lower values compared to test result except those in column 12L-0.6.For column 12L-0.6, the predicted lateral strength (19.76 kN) is higher than the test result (16.32 kN).
is might be a result of the concrete cover splitting along the column height at the early stage (as shown in Figure 5).It partially prevented the longitudinal bars to be able to fully develop their yield stresses.
To calculate lateral drift, the well-known Paulay model as explained in previous section was adopted.e plastic hinge length used in this study was equal to 0.5 h, and the limiting strain at ultimate drift is 0.003.From Table 4, it was evidently found that the model was overly conservative in predicting the lateral drift at gravity load collapse.e model under predicted the lateral drift varying from 65% to 77% compared to the test results.It was found that the use of limiting plastic hinge length of only 0.5 h or 17.5 cm from the base might not be suitable for low strength columns.Since the damage and cracking were not limited to only that region, the crack locations were significantly dependent on the type of longitudinal reinforcement, axial load level, and also strength of concrete.In addition, the use of limiting concrete crushing strain of 0.003 may be too low for such low strength concrete.e model to more precisely predict the lateral drift at gravity load collapse is still under development.e developing of constitutive model of such low strength concrete will be further developed and calibrated against the compressive load test of the low strength cylinder.
e recommendation of plastic hinge length model and new calculation approach will be presented in future.

Conclusions
is paper presents an experimental and numerical study on the cyclic performance of nonengineered reinforced concrete columns with distinct longitudinal bars and increased axial ratio.Based on the study, the test result revealed the following conclusions: (1) From the crack pattern and damage observation, it can be concluded that the longitudinal reinforcement ratio was a significant factor on the crack pattern of the column under cyclic loading.Vertical crack along longitudinal reinforcing with deformed bars was found.However, the crack pattern of longitudinal reinforcing round is limited near the base area.(2) From the hysteretic loop pattern observation, it can be concluded that the longitudinal reinforcement bars was a significant factor on the shape of hysteretic loop.e use of different bars types also influences energy dissipation.e energy dissipation is low when the deformed bars are used when compared to those using round bars.
(3) From the envelop curves of lateral load-drift relationship observation, it can be concluded that the lateral resistance of the low axial load columns was significantly dependent on and proportional to amount of longitudinal reinforcement.e lateral resistance of columns subject to low axial load level was evidently controlled by tensile resistance of steel since tension failure mode controlled the overall (4) From axial displacement and drift ratio relationship observation, it can be concluded that the initiation of axial shortening occurred at high drift compared to other columns.is is due to the fact the longitudinal reinforcements have a significant contribution in carrying the axial load (at low level).However, when the concrete cover was spalling at high drift, the bars were not effectively confined by concrete cover.Eventually, load-carrying capacity of the bars was lost due to compression buckling following by sharply axial shortening.Gravity load collapse of the column occurred as a consequence.In addition, the shortening behavior was likely to be controlled by behavior of concrete under compression.e axial shortening has initiated soon after the peak lateral resistance and continuously increased until gravity load collapse was imminent.(5) e well-known Paulay model was used to predict the drift capacity of the NRCC columns in this study.
It was found that the model was under predict lateral drift varying from 65% to 77% compared to the test results.

6 Figure 8 :
Figure 8: e envelope curve of all specimens.

Table 1 :
Summaries of mix properties for concrete.

Table 2 :
Properties of column specimens.

Table 3 :
Summaries of the column specimens test results.

Table 4 :
Maximum lateral strength and ultimate drift ratio.
behavior of such columns.e test results indicated that the axial load ratio affects maximum lateral load and drift capacity of all columns.