Experimental and Numerical Analysis of Hollow and Solid Reinforced Concrete Piers under Static and Impact Loadings

Yao, Pengfei; Zhu, Junyu; Zhu, Lu; Fang, Hai; Qian, Changgen

doi:https://doi.org/10.1155/2021/9926010

Shock and Vibration

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Abstract Introduction Discussion Conclusions Data Availability Conflicts of Interest Acknowledgments References Copyright Related Articles

Research Article | Open Access

Volume 2021 | Article ID 9926010 | https://doi.org/10.1155/2021/9926010

Experimental and Numerical Analysis of Hollow and Solid Reinforced Concrete Piers under Static and Impact Loadings

Pengfei Yao,¹Junyu Zhu,¹Lu Zhu,¹Hai Fang,¹and Changgen Qian¹

Academic Editor: Zengshun Chen

Received04 Mar 2021

Revised25 May 2021

Accepted19 Jul 2021

Published27 Jul 2021

Abstract

Collision on reinforced concrete (RC) piers by moving vessels or vehicles is a significant issue. This paper presents the static and impact behavior of RC piers with different hollow ratios. Three specimens were statically tested to obtain the load-displacement response. Low-velocity collision on eleven RC piers was conducted under the same velocity of 2.42 m/s. The damage process, failure mode, and force response were comprehensively analyzed. The experimental results indicate that the hollow ratio plays a significant role in the failure mode and ultimate load of RC piers under static and impact loadings. For RC piers with a hollow ratio of 0 and 0.4, the global failure dominated the damage process. However, failure of piers with a hollow ratio of 0.6 was governed by the local damage near the loading point. The static load capacities of the RC piers with a hollow ratio of 0.4 and 0.6 were 1.27% and 60.5% smaller than that of the solid pier, respectively. RC piers with a higher hollow ratio or lighter drop weight suffer smaller peak impact force. The increase of the longitudinal reinforcements leads to a promotion of the peak and mean impact force. Furthermore, the numerically predicted failure modes and impact load response show satisfactory agreement with the experimental results.

1. Introduction

Reinforced concrete (RC) structures are commonly used in bridge engineering across the world. Bridge piers are vulnerable to accidental impacts by moving vessels or vehicles, which may trigger localized damage or even total collapse of bridge structures [1–3]. The structural safety under impact load should be carefully assessed. The impact load due to vessel or vehicle collision is characterized by a high intensity but a short duration. Stress wave propagation, strain rate effect, and inertial effect should be considered in the complex dynamic analysis for RC structures [4]. Therefore, to ensure the structural efficiency and promote performance level during the whole life cycle, it is necessary to investigate the impact behavior of RC structures.

Assessments of the dynamic behavior of solid RC structures by experimental, numerical, and analytical techniques have been well documented in the literature. Fujikake et al. [5] carried out drop hammer impact tests and nonlinear analysis on RC beams considering variations of drop heights and longitudinal rebars. The amount of reinforcements had a significant effect on the failure modes. The dynamic response and impact force-time histories were mainly affected by the drop height and the flexural rigidity of RC beams. Kishi and Mikami [6] designed a great number of statically flexure-controlled RC beams with different cross section dimensions, clear spans, and reinforcement ratios. A performance-based design formula was proposed based on the results of the drop weight impact test. Zhao et al. [7] proposed a simplified method to predict the peak force and midspan displacement of simply supported RC beams subjected to impact loading. Guo et al. [8] investigated the dynamic deflection response of simply supported and fully clamped RC beams by theoretical and numerical methods. The results show that the maximum deflections are almost proportional to the input impact energy. Demartino et al. [9] conducted the horizontal impact test on shear-deficient RC piers with two boundary conditions, i.e., one fixed end and another cantilever or simply supported end. Obvious diagonal crack originated from column foot to the impact point, indicating a brittle shear failure mode. Fan et al. [10] performed the drop hammer test, compression test, and numerical analysis of circular RC columns to evaluate the residual axial capacity after impact. The residual capacity depended on the deformation and failure mode due to impact load. Ye et al. [11] investigated the effect of the slenderness ratio, reinforcement ratio, and axial compression ratio on the impact force and dynamic response of RC columns by a horizontal impact test machine. Results showed that the higher column slenderness ratio led to a larger value of the generalized ratio of peak impact force and longer impact duration. The enhancement of the reinforcement ratio and axial compression ratio could increase the average impact force. The existence of axial load relieved the residual deformation of the column. Zhou et al. [12] experimentally compared the impact response of RC piers with ordinary steel bars and stainless-steel bars under the protection of closed-cell aluminum foam. The results show that the impact forces of the stainless-steel RC piers were greater than that of ordinary RC piers, and the use of stainless-steel bars increased the possibility of shear failure modes. Yilmaz et al. [13] carried out the drop weight test to determine the influence of the axial load, impact energy, and shear reinforcement spacing on the impact performance of square RC columns. Wei et al. [14] conducted an experimental and numerical study of RC and ultra-high performance concrete (UHPC) columns under low-velocity impact loading. The results show that RC columns experienced brittle shear failure, while UHPC columns only showed minor flexural damage. Wu and Xu [15] experimentally evaluated the damage degree of stainless-steel-reinforced concrete piers with different longitudinal bars under four impact velocities and found that increasing the reinforcement ratio can obviously reduce the damage level.

In terms of vessel or vehicle impacts on RC bridge piers, numerical methods are widely used due to the efficiency and economic benefit. Sha and Hao [16, 17] conducted the pendulum impact tests and numerical simulations of circular RC piers under barge collision. Structure-related and load-related factors such as pier diameter, pier height, impact location, velocity, and mass were carefully examined. An empirical formula was proposed to calculate the barge impact force. Wang et al. [18] proposed a period-dependent impact factor method to estimate the dynamic response of bridge piers under vessel collision. The precision was validated by dynamic time history method of two example bridges. Sharma et al. [19] proposed the performance-based procedure to evaluate the dynamic shear force capacities of RC columns corresponding to performance levels. Li et al. [20] conducted a simulation analysis of vehicular collision on seismic designed RC piers and evaluated the damage level based on the damage index considering the pier diameter and shear-span ratio. Auyeung et al. [21] introduced a damage ratio index to correlate the damage level to target performance level in the design of bridges under vehicle collision. It was found that pier diameter governed the global failure type, and the transverse reinforcement ratio determined the local damage. Chen et al. [22] simulated the failure process of three-column RC piers under vehicle collision and proposed a safety assessment method to determine the shear failure. Do et al. [23] numerically investigated vehicle collision on RC bridge columns. The vehicle impact force, the dynamic shear capacities, and failure modes of RC columns can be predicted by a simplified analytical model.

Hollow RC structures are widely used as bridge piers owing to the proper balance between performance and cost [24, 25]. It is necessary to evaluate the influence of cross-sectional changes on structural safety under different load cases [26, 27]. However, few investigations on the low-velocity impact responses of hollow RC structures have been found in the literature. Most studies have focused on the seismic performance of hollow RC piers. Yeh et al. [28] conducted an experimental investigation on the seismic behavior of rectangular RC piers with different hollow ratios. The results showed that the main crack patterns of RC members were bending failure, bending-shear failure, and shear failure. Lee et al. [29] investigated the seismic behavior of circular hollow RC columns under cyclic loading. The damage process of flexure-controlled columns and compression-controlled columns varied, due to the different neutral axis location at failure. Qi et al. [30] performed the shaking table test of three scaled rounded rectangular hollow piers. Unlike the column response in common semistatic test, a second plastic hinge region appeared near the midspan of the pier. The increased volumetric stirrup ratio led to a better seismic performance.

Several investigations have been conducted on the lateral impact behavior of other hollow piers, such as partially concrete-filled steel tubular columns, concrete-filled double-skin steel tube columns, and hollow-core fiber-reinforced polymer (FRP) concrete-steel columns. Zhu et al. [31] experimentally and numerically investigated the lateral impact performance of hollow and partially concrete-filled steel tubular columns. The results indicated that the concrete filling height had a great influence on the local impact resistance and global crack patterns. Wang et al. [32, 33] experimentally and numerically investigated the influence of some key factors (such as impact height, hollow ratio, axial load) on the impact force and displacement response of concrete-filled double steel tubular members. An empirical formula for dynamic increase factor was proposed to calculate the lateral impact capacity. The results showed that the hollow ratio was the main parameter influencing the peak force and the suggested value for the hollow ratio was less than 0.7. Li et al. [34] conducted the field blast test, axial compression test, and numerical simulation to investigate the postblast behavior of concrete-filled double-skin steel tube columns. Damage could be rapidly evaluated by the proposed empirical formula calculating the residual axial capacity. Wang et al. [35] investigated the influence of axial force on impact performances of concrete-filled steel tubular members and proposed an analytical method to calculate the deflection by equivalent single degree of freedom (SDOF) model. Aghdamy et al. [36] analyzed the impact response of concrete-filled double-skin steel tube columns by numerical methods. The diameter-to-thickness ratio of outer tube, the slenderness ratio, and the hollow ratio were the key structure-related parameters affecting the impact response. Wang et al. [37] performed the drop hammer test of FRP-UHPC-steel double-skin tubular columns. The abovementioned literatures indicated that the hollow ratio had a significant influence on the impact response of concrete members.

Overall, most of the existing studies focus on the impact performance of solid RC beams and piers. However, the considerable number of studies on impact performance of hollow columns with steel-concrete, steel-concrete-steel, and FRP-concrete-steel materials can provide useful reference. However, there is limited experimental data related to the low-velocity impact behavior of hollow RC columns. Thus, the objective of this research is to evaluate the static and impact performance of RC piers with different hollow ratios. The vertical static tests on three RC piers were firstly carried out. The damage process, failure mode, and the load-midspan displacement were fully discussed. The impact tests on eleven rectangular RC piers were subsequently conducted. The design variables included the hollow ratio, the amount of longitudinal reinforcements, and the impact energy. Effect of these parameters on the failure mode and load response was comprehensively analyzed. Numerical models of the impact test were further developed using ANSYS/LS-DYNA. The simulated failure modes and load histories were compared with the experimental results.

2. Experimental Program

Vertical static tests and low-velocity impact tests were conducted. The test specimens, experimental setup, and layouts of instrumentation are discussed in detail.

2.1. Test Specimens

A total of nine hollow RC piers and five solid RC piers were cast with the same materials. Figure 1 presents the detailed dimensions of test specimens. All RC piers were 1550 mm in length, 300 mm in height, and 200 mm in dimension. A RC footing with a cross section of 410 mm × 480 mm was built to create fully fixed boundary condition. The RC piers were designed according to two variables: the hollow ratio and the amount of longitudinal reinforcements N. The hollow ratio is defined as the ratio of to A. The parameters and A are the cross-sectional area of the inner void and the solid pier, respectively. The wall thickness for two types of hollow piers are 44 mm and 27 mm. The layouts of the reinforcements on the cross section are shown in Figure 2. The diameter of longitudinal and shear rebars was 6 mm for all specimens. The spacing of shear reinforcements was 100 mm. The yield strength of all reinforcements was 310 MPa. The cubic compressive strength of concrete was 30 MPa.

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Three specimens were tested under static loading. The impact test involved eleven piers, including three groups, i.e., DA group with = 0, DB group with = 0.4, and DC group with = 0.6. Details of the specimens are summarized in Table 1. Three main parameters including the hollow ratio , the impact energy E, and the total number of longitudinal reinforcements N were considered. The following naming rules are used to characterize each specimen. The letter “S” or “D” denotes that the specimen is under static or dynamic loading. The letters “A,” “B,” and “C” represent a hollow ratio of 0, 0.4, and 0.6, respectively. The numeric value “20” or “30” denotes that N = 20 or N = 30. The last Roman numerals “I,” “II,” and “III” denote that the mass of the impactor (M) is 230 kg, 330 kg, and 430 kg, respectively. The impact height was designated to be constant as 0.3 m; therefore all specimens had an identical impact velocity with a value of 2.42 m/s. Thus, the impact energy was changed by adjusting the drop weight.

2.2. Test Setup and Instrumentation

Figures 3(a) and 3(b) show the experimental setup for the vertical static test and low-velocity impact test of the RC piers, respectively. All piers were fixed at one end and simply supported at the other end. A steel beam placed on the concrete base was bolted to the floor to achieve the fixed boundary condition. A steel roller-bearing was installed at a distance of 150 mm from the free end of the pier, as depicted in Figure 4(a). For impact loading, an additional top steel roller-bearing connected to the bottom one was used to prevent the pier from vertical bouncing.

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In the static test, a 100-ton Jack was employed to exert vertical force with an interval of 5 kN. A T-shape steel loading head was placed at the midspan to transfer local linear force to each specimen. The 40Cr steel loading head had a semicircular nose with a radius of 25 mm, as illustrated in Figure 4(b). The vertical deflection at the midspan was measured by a YHD displacement sensor with a range of 200 mm. In addition, another two small range displacement sensors were fixed at the supported ends.

The low-velocity dynamic test was conducted by a drop hammer impact system in Nanjing Tech University, China. The drop hammer consists of a hammer body with adjustable weight and a changeable hammer head. The hammer head for the impact test was the T-shape one used in the static test. The mass of the hammer head is 30 kg. The mass of the hammer body can vary from 200 kg to 1200 kg with an interval of 50 kg. Therefore, the selected drop weights were 230 kg, 330 kg, and 430 kg. The test results were automatically recorded at a sampling rate of 400 kHz.

3. Test Results and Discussion

3.1. Response under Static Loading

3.1.1. Crack Patterns

Figure 5 presents the failure modes of specimens under static loading. Damage was concentrated in the midspan area. The experimental results showed that the wall thickness of concrete pier played a significant role in the damage process and failure mode. For specimen SA20, one vertical crack initially occurred near the lower edge of the pier, with the corresponding load being 100.9 kN. The flexural crack then developed and propagated vertically toward the upper edge. Meanwhile another vertical crack was observed near the initial flexural crack. Since the maximum bending moment occurred at the midspan, the flexural cracks were recognized around the middle of the pier. Another two diagonal cracks occurred at the half span near to the fixed end, whereas no oblique cracks were observed at the half span near to the simply supported end. The main reason was the different shear force distribution. The cracks became wide when the load increased. The bending crack eventually developed as the primary crack. Longitudinal steel rebars in the textile region broke after the maximum load. Hence, the flexural crack width and the midspan displacement continued to grow. The failure was governed by two vertical cracks at the midspan, indicating specimen SA20 exhibited the overall bending failure mode.

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Crack distribution of specimen SB20 was similar to that of specimen SA20. However, obvious spalling of the concrete cover was observed in the front and rear side of the pier. Concrete in the upper compression region was crushed, while fracture of reinforcements in the lower tensile zone did not happen. Thus the final main flexural width of specimen SB20 was much smaller than that of specimen SA20. The specimen with a hollow ratio of 0.4 exhibited the overall bending failure mode, as well as the local damage mode.

For specimen SC20, a tiny vertical crack and a small oblique crack originally emerged at the bottom side of the pier. The concrete beneath the hammer head was partially crushed at a load of 40 kN. As the load continued to increase, the bottom cracks expanded slowly and failed to develop as main cracks. However, the upper crushed area obviously enlarged, indicating local failure developed into the main damage. Moreover, indentation into concrete near the load point of specimen SC20 was severe, due to thin wall thickness and small local stiffness.

3.1.2. Load-Midspan Displacement Relationships

The load-midspan displacement curves obtained from static tests are illustrated in Figure 6. The characteristic points such as ultimate load and the corresponding displacement are identified. When the concrete crack firstly appeared on specimen SA20, the load was 100.91 kN and the midspan displacement was 1.68 mm. Compared with specimen SA20, the cracking loads of specimens SB20 and SC20 were reduced by 23.4% and 62.4%, respectively. Meanwhile the corresponding midspan displacement was increased by 73.8% and decreased by 18.4%, respectively. The elastic stiffness of the pier seems to have a great influence on the static cracking performance. The larger the elastic stiffness, the bigger the cracking load. The ultimate static loads for specimens SA20, SB20, and SC20 were 142.73 kN, 140.91 kN, and 56.36 kN, respectively. Results indicate that a relatively small hollow ratio (i.e., = 0, 0.4) has little effect on the static load capacity. Nevertheless, an excessive increase in the hollow ratio (i.e., = 0.6) can significantly reduce the ultimate load.

The vertical load of specimen SA20 dropped from 120 kN to 104 kN due to the fracture of bottom tensile reinforcements. Then the vertical load remained basically the same, but the midspan deflection increased from 16.3 mm to 30.36 mm, revealing a platform in the load-displacement curve. For specimen SC20, the local crushing of concrete and the buckling of reinforcements contributed to the rapid decrease of the load curve. In addition, the load-displacement curve of specimen SC20 showed a rising tendency at the final stage. This abnormal rising was mainly caused by resistance from the upper rebars after the full crushing of concrete near the loading point. Based on the shape of the load-displacement curves, specimens SA20 and SB20 generally exhibited a certain ductility, while specimen SC20 showed the brittle behavior.

3.2. Response under Impact Loading

3.2.1. Failure Mode

Damage of solid piers under impact loading is shown in Figure 7. Specimen DA20I had no obvious damage, except for slight concrete cover spalling in the local region underneath the drop hammer. Other specimens of DA group exhibited narrow vertical cracks initiating from the underside. Specimen DA30III possessed more tensile longitudinal reinforcements than specimen DA20III, indicating minor bending cracks.

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Figure 8 demonstrates the crack patterns for specimens of DB group subjected to impact loading. All specimens except for DB20I exhibited vertical cracks as well as diagonal shear cracks, indicating bending-shear failure. The shear cracks fully developed and located within one-quarter to one-half span from the fixed end. Meanwhile another two parallel shear cracks originating from the fixed end were observed on specimen DB30III. This is most likely due to the increase in longitudinal reinforcements, resulting in higher bending capacity and being inclined to shear damage. Since the lowest impact energy is of specimen DB20I, only oblique cracks were observed as shown in Figure 8(a).

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Figure 9 displays the failure modes of specimens of DC group under impact loading. Both indentation into concrete near the impact region and local crushing of concrete appeared on all specimens. This can be attributed to the fact that the RC pier with a hollow ratio of 0.6 has a small area of concrete, i.e., a small local stiffness; therefore the structure response is concentrated to the local region near the load point. It is similar to the response of specimen SC20 under static loading. In addition, specimen DC20II exhibited two diagonal shear cracks.

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To sum up, the hollow ratio of RC piers played an important role in the failure behavior under impact loading. Failure modes for all piers are listed in Table 1. RC piers with a hollow ratio of 0 and 0.4 generally exhibited the global failure modes, whereas failure of hollow piers of DC group was governed by local damage near the drop hammer. Solid piers with drop weights of 330 kg and 430 kg failed in a flexural mode. Specimens of DB group with hammer weights of 330 kg and 430 kg exhibited the bending-shear failure modes.

3.2.2. Impact Force

The impact force mainly depends on the impact energy, the local stiffness of the contact surface, and the global stiffness of the specimen. Figure 10 demonstrates time histories of the impact force for specimens with different hollow ratios. Specimens DC20II and DC30I exhibited distinct impact load-time history curves. The impact load near the peak value was relatively steady. However, the impact load curves for other specimens developed the same trend. The impact force sharply increased to the first peak value, then reduced rapidly, developed several other peak values, and finally reduced to zero. The first peak lasted about 2 ms. The total duration time ranged from 10.3 ms to 18.35 ms.

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The peak impact force , the total duration time , and the average impact force are tabulated in Table 1. The values of three physical quantities can be obtained from the impact force-time curves. is the transient maximum value of the impact force. is the total duration of the load curve. is the average value of the impact force during the time length of . is defined as the ratio of the area enclosed by the force-time curve to the duration time.

It can be seen from Figure 10 and Table 1 that drop weight had a significant effect on the transient peak load. Compared with specimen DA20I, the maximum impact force for specimens DA20II and DA20III was increased by 59.7% and 81.2%, respectively. Specimens of DB group and DC group also confirmed this trend. When the drop weight changed from 230 kg to 330 kg, the duration times for specimens of DA group, DB group, and DC group were prolonged by 24.3%, 15.4%, and 29.2%, respectively. Meanwhile the corresponding average loads were increased by 98.9%, 49.5%, and 21.2%, respectively. It is noted that the growth rates of average force tended to slow down, for the impact case with a higher hollow ratio. However, the average load was almost unchanged when the drop weight varied from 330 kg to 430 kg.

The impact force responses with different drop weights are shown in Figure 11 and Table 1. The effect of the hollow ratio on impact force can be concluded. It is evident that RC pier with a higher hollow ratio suffers smaller peak impact force due to the relatively low contact stiffness and overall stiffness. The maximum impact loads for specimens DB20I and DC20I were 21.5% and 60.7% lower than that of specimen DA20I, respectively. With the impact case of M = 330 kg, the peak impact force values for specimens of DA group, DB group, and DC group were 163.85 kN, 91.84 kN, and 63.78 kN, respectively. The peak impact loads of specimens DB20II and DC20II were 56.1% and 38.9% of the corresponding solid pier, respectively. The peak impact force of specimen DB20III was 130.27 kN, which was 29.9% lower than specimen DA20III. The mean impact force exhibited small variations with the collision case of = 0 and = 0.4, regardless of N = 20 or N = 30. But an apparent drop of average force emerged, as the hollow ratio changed from 0.4 to 0.6. Results indicate that a smaller hollow ratio (i.e., = 0, 0.4) produces minor effect on the average impact load, but a relatively large hollow ratio (i.e., = 0.6) can significantly decrease the average impact load. The effect of the hollow ratio on average impact force was similar to that on static ultimate load.

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When the total longitudinal reinforcements varied from 20 to 30, the stiffness of the specimens became larger. Consequently, the peak and mean impact force enlarged, and the duration time was reduced, as shown in Figures 10 and 11(c) and Table 1. For specimens DA20III and DA30III, the peak impact force values were 185.90 kN and 254.20 kN, respectively, increasing by 36.7%. Meanwhile the corresponding average force increased by 42.3%, and the related duration time was slightly shortened. For specimens from DB group and DC group varying the longitudinal rebars, the ultimate impact loads were increased by 2.85% and 45.6%, respectively. However, the mean impact force values were increased by 48.9% and 43.8%, respectively.

From the impact results, it can be concluded that the impact energy (i.e., the drop weight) and the hollow ratio as well as the amount of longitudinal reinforcements had a significant effect on the peak force. With the case of = 0 and = 0.4, or the case of M = 330 kg and M = 430 kg, the average load had a relatively small variation. When the drop weight varied from 230 kg to 330 kg, or the hollow ratio changed from 0.6 to 0.4, the average load was substantially enhanced. An increase of the longitudinal reinforcement led to the promotion of the peak and mean impact force.

4. Finite Element Analysis of RC Piers under Impact Loading

4.1. Finite Element Model

Numerical models of drop impact on RC piers were established by the explicit finite element program ANSYS/LS-DYNA [38], as shown in Figure 12. A mesh size of 10 mm was used for the RC piers. This element size was selected based on mesh sensitivity analysis. The longitudinal and transverse rebars were discretized into 10 mm long beam elements. The drop hammer and the support rollers were meshed with a minimum mesh size of 6 mm and a maximum mesh size of 10 mm. The pier foot was prevented from moving in all directions. The support rollers were simulated with constrained vertical displacement but free rotation. The initial velocity was assigned to the drop hammer. For specimen DB20III, the drop hammer, the concrete pier, and the support rollers were modeled using 84038, 130680, and 2112 eight-node solid hexahedron elements, respectively. The numerical models for other specimens differed in the total element number of the drop hammer, the concrete pier, and the reinforcements, due to the variations of the drop weight, the hollow ratio, and the amount of rebars.

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The contact surfaces between each part were carefully defined. Both surface-to-surface and node-to-surface contact algorithms were employed. The former algorithm was used to model the interactions between the loading impactor, the support rollers, and the RC pier, whereas the latter algorithm was selected for the contact between the steel rebars and the drop hammer. The dynamic and static coefficients of friction were both set as 0.3 [39, 40].

4.2. Material Models

The plastic kinematic model from LS-DYNA material library [38] was selected for the drop hammer and the longitudinal and transverse rebars. The strain rate effect was considered by the Cowper-Symonds model. The main parameters were defined as follows: strain rate parameter C = 40.4 s⁻¹, strain rate parameter [41], strain hardening parameter = 0, and yield stress for reinforcing bars = 310 MPa.

The continuous surface cap model [38] was employed to represent the nonlinear behavior of concrete pier. This material model was validated to predict the dynamic behavior of RC structures under low-velocity impact loading [11, 21, 41]. The main parameters were automatically generated by defining the unconfined cylinder compressive strength and aggregate size with a value of 24 MPa and 10 mm, respectively. The erode parameter controlling element erosion was 1.05.

MAT_RIGID [38] was used to model the support rollers. Young’s modulus and Poisson’s ratio of the steel material were defined since unrealistic values may result in numerical problems in contact.

4.3. Comparisons of the Numerical and Experimental Results

Figure 13 shows the simulated concrete damage contours for the representative specimens. Effective plastic strain ranged from 0 (blue) to 1 (red). Vertical cracks, diagonal shear cracks, and local crushing of concrete were reasonably predicted. The predicted damage distribution was basically consistent with that of the experimental results.

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Figure 14 illustrates the comparisons of the simulated and experimental impact force histories. The predicted load curves generally exhibited a similar shape with the experimental results, in spite of some deviations in the peak value of feature points. The numerical results tend to underestimate the peak force and the impact duration except for specimen DC20II. The average loads obtained from the predicted force-time curves for specimens DA20II, DB20III, DB30III, and DC20II were 53.27 kN, 54.49 kN, 65.96 kN, and 26.56 kN, respectively. The average loads were estimated with an error less than 11.8%.

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5. Conclusions

This study investigated the static and impact behavior of RC piers with different hollow ratios. Three specimens were tested under static loading. Low-velocity impact tests were carried out by a drop hammer impact system. The impact test involved eleven piers divided into DA group, DB group, and DC group. Three parameters were considered, namely, the hollow ratio, the amount of longitudinal reinforcements, and the impact energy. The damage process, failure mode, and force response were comprehensively analyzed. Numerical simulation for representative specimens was performed. The results presented in this paper support the following conclusions.(1)The hollow ratio played a significant role in the damage process and failure mode of all RC piers. The solid RC pier under static loading exhibited the overall bending failure mode. Specimen SC20 showed only local damage. Two types of damage were observed on specimen SB20. When subjected to impact loading, RC piers with a hollow ratio of 0 and 0.4 exhibited the global failure modes, whereas failure of hollow piers of DC group was governed by the local damage near the drop hammer.(2)The load-displacement curves indicated specimens SA20 and SB20 generally exhibited a certain ductility, while specimen SC20 showed the brittle behavior. A relatively small hollow ratio (i.e., = 0, 0.4) had little effect on the static load capacity. However, excessive increases in the hollow ratio (i.e., = 0.6) significantly reduced the static ultimate load.(3)The impact energy (i.e., the drop weight) and hollow ratio, as well as the number of longitudinal reinforcements, had a significant effect on the peak force. With the case of = 0 and = 0.4, or the case of M = 330 kg and M = 430 kg, the average load had a relatively small variation. When the drop weight varied from 230 kg to 330 kg, or the hollow ratio changed from 0.6 to 0.4, the average load was substantially enhanced. The increase of the longitudinal reinforcements led to a promotion of the peak and mean impact force.(4)According to the failure pattern and load curves under static and impact loadings, a hollow ratio of 0.4 is suggested in the preliminary design of a RC bridge pier due to a balance of structure cost and load resistant characteristic.(5)The numerical models of RC piers were established. The simulated failure modes and predicted load response showed satisfactory agreement with the experimental results.

Data Availability

The data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest

The authors declare that there are no conflicts of interest regarding the publication of this paper.

Acknowledgments

This study was supported by the National Natural Science Foundation of China (Grant no. 52078248), the Excellent Youth Foundation of Jiangsu Province (Grant no. BK20190034), and Postgraduate Research and Practice Innovation Program of Jiangsu Province (Grant no. KYCX21_1148).

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Copyright © 2021 Pengfei Yao et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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