Exploring the Synergy: Experimental and Theoretical Investigation of Steel and Glass Fiber Reinforced Polymer (GFRP) Reinforced Slab Incorporating Alccofine and M-Sand

Introduction: This study investigates the Experimental and Theoretical Investigation of Steel and Glass Fiber Reinforced Polymer (GFRP) Reinforced Slab Incorporating Alccofine and M-sand. Objective: Specific objectives include evaluating the mechanical properties and structural behaviour of steel and GFRP-reinforced one-way slabs and comparing experimental and theoretical predictions. Methods: Four different mix proportions were arrived at, comprising both conventional concrete and Alccofine-based concrete. In each formulation, a combination of normal river sand and M-sand was utilized. Results: Concrete with Alccofine exhibits superior mechanical properties, while M-sand incorporation minimally affects strength but reduces reliance on natural sand. GFRP-reinforced slabs display distinct brittle behaviour with significant deflections post-cracking, contrasting steel-reinforced slabs’ gradual, ductile failure. Discrepancies between experimental data and design recommendations underscore the need for guideline refinement. Conclusion: Alccofine and M-sand enhance concrete properties, but reinforcement type significantly influences slab behaviour. GFRP-reinforced slabs, though exhibiting lower values than steel, offer advantages in harsh environments, warranting further optimization.

Damage response of conventionally reinforced two-way spanning concrete slab under eccentric impacting drop weight loading

Reinforced concrete(RC)structures are generally designed to carry quasi-static gravity loads through almost indispensable components namely slab,however,it may be subjected to high intense loads induced from the impact of projectiles generated by the tornado,falling construction equipment,and also from accidental explosions during their construction and service lifespan.Impacts due to rock/boulder falls do occur on the structures located especially in hilly areas.Such loadings are not predictable but may cause severe damage to the slab/structure.It stimulates structural engineers and researchers to investigate and understand the dynamic response of RC structures under such impulsive loading.This research work first investigates the performance of 1000×1000×75 mm^(3)conventionally reinforced two-way spanning normal strength concrete slab with only tension reinforcement(0.88%)under the concentric impact load(1035 N)using the finite element method based computer code,ABAQUS/Explicit-v.6.15.The impact load is delivered to the centroid of the slab using a solid-steel cylindroconical impactor(drop weight)with a flat nose of diameter 40 mm,having a total mass of 105 kg released from a fixed height of 2500 mm.Two popular concrete constitutive models in ABAQUS namely;Holmquist-Johnson-Cook(HJC)and Concrete Damage Plasticity(CDP),with strain rate effects as per fib MODEL CODE 2010,are used to model the concrete material behavior to impact loading and to simulate the damage to the slab.The slab response using these two models is analyzed and compared with the impact test results.The strain rate effect on the reinforcing steel bars has been incorporated in the analysis using the Malvar and Crawford(1998)approach.A classical elastoplastic kinematic idealization is considered to model the steel impactor and support system.Results reveal that the HJC model gives a little overestimation of peak displacement,maximum acceleration,and damage of the slab while the predictions given by the CDP model are in reasonable agreement with the experimental test results/observations available in the open literature.Following the validation of the numerical model,analyses have been extended to further investigate the damage response of the slab under eccentric impact loadings.In addition to the concentric location(P1)of the impacting device,five locations on a quarter of the slab i.e.,two along the diagonal(P2&P3),the other two along the mid-span(P4&P5),and the last one(P6)between P3 and P5,covering the entire slab,are considered.Computational results have been discussed and compared,and the evaluation of the most damaging location(s)of the impact is investigated.It has been found that the most critical location of the impact is not the centroid of the slab but the eccentric one with the eccentricity of 1/6th of the span from the centroid along the mid-span section.

Pressure-impulse diagram with multiple failure modes of one-way reinforced concrete slab under blast loading using SDOF method

Two loosely coupled single degree of freedom (SDOF) systems were used to model the flexural and direct shear responses of one-way reinforced concrete slabs subjected to explosive loading. Blast test results show that the SDOF systems are accurate in predicting the failure mode of the slab under blast loads by incorporating the effects of the strain rate effect caused by rapid load application. Based on different damage criteria, pressure-impulse (P-I) diagrams of the two failure modes were analyzed with the SDOF systems. The effects of span length, concrete strength, and reinforcement ratio of the slab on the P-I diagram were also investigated. Results indicate that a slab tends to fail in direct shear mode when it is of a smaller span length and tends to fail in flexure mode when it is of a larger span length. With the increase of the concrete strength or reinforced ratio, both the flexure and shear capacity increase. Based on numerical results, a simplified method and a semi analytical equation for deriving the P-I diagram are proposed for different failure modes and damage levels.

Blast resistance of air-backed RC slab against underwater contact explosion

Reinforced concrete(RC)structures are common in engineering,and usually exposed to air or water,may be subjected to various blast scenarios.This paper aims to investigate the blast resistance of an airbacked RC slab against underwater contact explosions(UWCEs).A detailed numerical model based on CLE method considering explosive,water,air,and RC slab is developed to examine the structural behavior of the air-backed RC slab due to UWCEs.At first,the reliability of the numerical method is validated by comparing the numerical results of an UWCE test with experimental data.Then,the difference in dynamic behavior of air-backed and water-backed RC slabs due to UWCEs is explored with the calibrated model.The results indicate that the blast response of the air-backed slab induced by UWCE is fiercer than that of water-backed slab with equal charge mass.In addition,parametric studies are also conducted to explore the effects of the charge mass,standoff distance,reinforcement spacing,concrete compression strength,and boundary condition on the blast performance of the air-backed RC slab.

火灾与爆炸耦合作用对RC板力学性能影响研究

为研究火灾下钢筋混凝土(RC)板抗爆性能,利用ABAQUS有限元软件对已有试验进行模拟并验证火灾下RC板高温模型以及RC板常温爆炸模型的有效性。在此基础上,分析了火灾下RC板的爆炸工作机理,研究了受火时间、不同方位角以及不同爆炸位置对RC板在火灾下抗爆性能的影响。结果表明:火灾下的RC板受爆炸荷载作用时,板中部首先发生剪切破坏,随后楼板整体发生受弯破坏;随着受火时长增加,混凝土受高温劣化,钢筋强度下降,RC板的抗爆性能下降严重;在受火时长120 min工况下,板角爆炸相比板边、板中爆炸的峰值位移分别增加了134.4%、150.9%;在受火时长180 min工况下,板角爆炸相比板边、板中爆炸的峰值位移分别增加了138.4%、159.9%;不同位置爆炸对RC板影响较明显,其中板中爆炸对RC板的破坏程度最高,且RC板破坏越严重,其动力响应持续时间越长;在受火时长120 min工况下,爆炸方位角为60°和90°的RC板峰值位移相比爆炸方位角30°的RC板峰值位移分别减小了4.4%、2.4%,不同方位角爆炸对RC板的影响不明显。

竖向荷载下装配式RC浅圆仓仓顶板横板向传力性能试验研究

装配式RC浅圆仓仓顶结构属于锥壳结构,在电缆线和仓顶集中荷载下,存在较大的横板缝方向传力需求。为研究装配式RC浅圆仓仓顶结构横板向传力性能,设计并完成了4个装配式仓顶板和2个现浇板在竖向荷载下的静载试验,对试件的破坏形态、挠曲变形、应变发展等进行分析。结果表明:板缝连接件具有良好的横板向传力性能,带板缝预制仓顶板具有较好的承载力和刚度。连接件和板缝的数量变化对装配式仓顶板横板向传力及刚度影响较大。连接件数量增多和板缝数量的减少,可有效提高装配式仓顶板横板向传力性能,增大弹性变形,提高其承载力和刚度;上部盖板锚板可以有效地传递板缝弯曲压应力;开孔板先于板缝连接件锚筋屈服,提高装配式夹层板的横板向刚度的可修复性。

全装配式RC楼盖横板向传力性能试验研究及理论分析

为研究分布式连接全装配RC楼盖(DCPCD)横板向传力性能,完成了8个对边简支试件的竖向静载试验。基于共轭法提出了DCPCD横板向刚度的计算方法,并研究了板缝数量、板缝连接件数量、楼盖跨度和横板向与顺板向刚度比等参数对DCPCD横板向传力性能的影响。结果表明:DCPCD试件的板缝连接件受力性能良好,可有效地传递横板向弯矩和剪力,并能较好地协调相邻预制板的变形;基于共轭法的DCPCD横板向刚度计算方法的精度比最小截面刚度法和折线变形法高;减少板缝数量、增加板缝连接件数量均可有效改善楼盖横板向的传力性能,提高楼盖的竖向承载力和刚度;基于楼盖承载力与振动舒适度的要求,建议四边简支楼盖横纵向刚度比的取值范围为0.3~0.75。

Degradation and Mechanism of the Mechanics and Durability of Reinforced Concrete Slab in A Marine Environment

An experimental research was conducted to determine the corrosion and bearing capacity of a reinforced concrete（RC） slab at different ages in a marine environment.Results show that the development of corrosion-induced cracks on a slab in a marine environment can be divided into three stages according to crack morphology at the bottom of the slab.In the first stage,cracks appear.In the second stage,cracks develop from the edges to the middle of the slab.In the third stage,longitudinal and transverse corrosion-induced cracks coexist.The corrosion ratio of reinforcements nonlinearly increases with the age,and the relationship between the corrosion ratio of the reinforcements and the corrosion-induced crack width of the concrete is established.The flexural capacity of the corroded RC slab nonlinearly decreases with the age,and the model for the bearing capacity factor of the corroded RC slab is established.The mid-span deflection of the corroded RC slab that corresponds to the yield of the reinforcements linearly increases with the increase in corrosion ratio.Finally,the mechanisms of corrosion morphology and the degradation of the mechanical properties of an RC slab in a marine environment are discussed on the basis of the basic theories of steel corrosion in concrete and concrete structure design.

Seismic behavior of slab-structural wall junction of RC building

In high seismic zone regions, slender reinforced concrete structural walls are commonly used in high-rise buildings as a main lateral load resisting element. These walls are very effective in limiting the lateral drift of the building due to their large in-plane stiffness. However, the presence of floor slabs influences the behavior of the shear wall. Also, the current design requirements do not account for the presence of floor slabs. To understand the behavior of wall-slab junctions and address the shortcomings of the current design requirements, the influence of two parameters, namely(a) aspect ratio and(b) longitudinal reinforcement ratio on the behavior is studied numerically. It is observed that the presence of floor slabs at different levels tends to partition the wall into squat wall panels between two consecutive floors. The wall-slab junctions show large stress concentrations arising from the strut action in the squat panels. It is also observed that the floor slabs can get significantly damaged near the wall-slab junction for lower vertical reinforcement ratios in the wall. Thus, the current codeprescribed minimum reinforcement in shear walls is not sufficient and needs to be revisited at for improved performance.

Comparative Study between Waffle and Solid Slab Systems in Terms of Economy and Seismic Performance of a Typical 14-Story RC Building

In order to maximize the return of investments and at the same time improve the quality in the construction industry of midrise buildings, it is very important to derive an optimal solution to the building structural system, which would facilitate faster and easier construction activities with minimal quantity of construction material, while maintaining the satisfactory level of building safety and performance. This paper makes a comparative study between a ＂solid＂ and a ＂waffle＂ slab system. A typical 14-story RC building structure is selected as an example for this study purpose. The first part of this study is focused in deriving an optimal solution for a solid and waffle slab system which are later on considered as constituents of all stories of the 14-story building. In the second part, it is elaborated the effect of both slab systems over the 14-story building model. This study aims to emphasize the advantages of mid-rise buildings constituted of waffle slab system over the buildings characterized with solid types of slabs, in terms of economy, structural safety and performance.

爆炸荷载作用下RC梁-板子结构抗连续倒塌动力效应研究

为研究爆炸荷载作用下建筑结构的抗连续倒塌性能。通过ANSYS/LS-DYNA有限元软件对爆炸荷载作用下钢筋混凝土(reinforced concrete,RC)梁-板子结构的抗连续倒塌动力效应进行研究,并对混凝土强度、钢筋配筋率和跨高比等参数进行拓展分析。研究结果表明,通过瞬间去柱模拟爆炸去柱会造成结构残余承载力和结构局部损伤程度偏保守或者偏高的后果。混凝土强度对结构的动力效应影响显著,当混凝土强度大于C40时,结构的压膜及压拱机制已足够阻止连续倒塌的发生。配筋率的提高对压拱机制抗力影响不大,但能显著提高悬链线机制的抗力。跨高比对结构抗力机制的发展有着显著的影响,降低跨高比可以提高结构压拱和压膜机制抗力,但是对悬链线机制抗力影响不大。

汶川地震中典型RC框架结构的震害仿真与分析

四川汶川地震中,一些钢筋混凝土框架结构柱端出现严重的塑性铰,而梁端震害反而较轻,该结果不符合抗震设计的预期目标。基于地震灾区某典型框架结构的震害调查,对该框架结构进行深入的有限元仿真分析。保持该框架结构质量分布基本不变的情况下,建立3种不同的计算模型:①纯框架模型;②带楼板的框架模型;③带楼板-填充墙的框架模型。对3种模型分别进行三维弹塑性时程动力分析,分析中采用本次地震中什邡八角镇的强震记录。分析结果表明,按照规范设计的框架结构无法保证"强柱弱梁"抗震设计目标的实现;填充墙的存在影响结构的破坏机制,填充墙上下设置不均匀容易导致框架软弱层。建议框架结构的设计应充分考虑楼板和填充墙对框架抗震性能的影响,适当提高柱的刚度和承载力,结构弹塑性分析应采用考虑结构楼板和填充墙的计算模型。

楼板对RC空间框架结构抗连续倒塌性能影响试验研究

为研究楼板对RC空间框架结构抗连续倒塌性能的影响作用,文章以汶川地震中完全倒塌的漩口中学教学楼为原型结构,设计3个单层2×2跨1/3缩尺模型,包括2个带楼板子结构和1个纯框架子结构,通过拟静力加载试验研究RC框架结构在拆除中柱状态下的连续倒塌破坏过程。试验结果表明:纯框架子结构首先进入梁机制阶段,框架梁内产生轴向压力,产生'压拱效应',在梁端部截面抗弯承载力丧失后,进入悬链线机制阶段,依靠梁内部钢筋拉结力抵抗上部荷载。对比分析带楼板子结构与纯框架子结构试验结果,由于楼板的'薄膜效应'使梁机制峰值承载力提高了145%,悬链线机制峰值承载力提高了75%,楼板显著提高了梁机制和悬链线机制的抗连续倒塌能力。增加板厚增加梁板的'压拱效应',极大提高梁机制承载力,然而大变形下梁板开始不协同作用,板发生冲切破坏,降低了悬链线阶段承载力和延性。

220 kV全装配式混凝土户内变电站配电装置楼结构抗震设计

在国家电网“两型一化”发展战略引领下,提出了一种新型全装配式钢筋混凝土(reinforced concrete,RC)户内变电站结构,该结构由全装配式RC框架结构和分布式连接全装配RC楼盖(discretely connected precast RC floor,DCPCF)组成。介绍了新型全装配式RC户内变电站结构数值分析方法,分析了某220 kV全装配式RC变电站配电装置楼地震响应规律,并与同型现浇结构进行了对比分析。结果表明:全装配式变电站满足抗震设计规范要求,结构安全可靠;全装配式变电站受由楼盖参与的高阶振型影响较大,设计时需考虑更多振型的参与;与同型现浇结构相比,在双向水平地震作用下,全装配式RC变电站整体结构的楼盖发生了较大的平面内变形,进而使得二者的地震响应存在较大差异;对结构大开洞楼层进行了楼板应力补充分析,发现DCPCF的应力小于现浇楼盖,结构的不规则布置使部分连接件所在区域出现应力集中,建议对楼板应力集中区域采取加强措施。研究结果可为全装配式变电站建筑结构的研究和应用提供参考。

考虑周边结构约束影响的RC框架结构防连续倒塌性能研究

为了考察周边结构约束对钢筋混凝土(RC)框架结构防连续倒塌承载能力的影响,该文通过QianK等进行的中柱移除的框架子结构拟静力试验,校核了论文中ABAQUS软件建立的框架子结构精细有限元分析模型的准确性。模拟所得的荷载位移曲线与试验曲线吻合良好,较好地模拟了中柱移除至子结构破坏的全过程。在成功进行模型校核的基础上,通过改变平面框架两侧边跨的约束情况,分析了两侧边跨约束对所研究子结构防连续倒塌承载力的影响;其次通过对比考虑楼板与不考虑楼板的单层空间结构的承载力,分析了楼板在结构防连续倒塌受力过程中对提高压拱阶段和悬链线阶段承载力的作用,讨论了楼板对连续倒塌各个受力阶段不同的影响;最后建立了多层空间框架结构模型,研究框架底层柱移除过程中结构的承载能力,分析发现楼层数的增加,成倍地提高框架结构承载力,并对连续倒塌各个受力阶段产生不同的影响。

不等跨布置RC空间梁-板结构竖向倒塌能力数值研究

为研究不等跨布置下RC空间梁-板结构抗连续倒塌能力,利用有限元软件ABAQUS建立在关键柱失效下空间框架结构精细化模型,通过Pushdown分析方法对试验子结构进行数值模拟。分析关键柱失效位置、梁板参数、楼板的损伤性能以及梁端截面内力对倒塌能力的影响。分析结果显示:内柱失效工况下楼板能提供承载力的40%~50%,边柱失效工况下楼板能提供20%~30%的承载力,角柱失效工况下楼板能提供15%~25%的承载力;梁跨度越大,柱失效后结构承载力越低,等跨设计的结构较不等跨设计受力存在“滞后性”,且横向约束对无板结构承载力基本上没有影响;梁板参数对提高结构承载力以及延性有重要影响;小变形下楼板损伤性能可以反映楼板的屈服模式,从而可推测楼板裂缝分布;最后提出了不等跨布置下考虑楼板影响的承载力计算公式。

分布式连接全装配RC楼盖竖向承载力与变形分析

在分布式连接新型全装配RC楼盖中,板与板之间通过连接件连接实现横板向传力。为研究新型楼盖竖向承载力计算方法,进行了新型楼盖在竖向荷载作用下的内力与变形分析。结果表明:基于正交各向异性弹性薄板小挠度理论和单三角级数法得到四边简支新型楼盖在竖向均布荷载作用下的弯矩与挠度表达式,提出了新型楼盖横板向刚度计算方法,并通过与试验和有限元结果对比,验证了所提方法的准确性;新型楼盖的挠度在两个方向呈空间抛物面分布,表明新型楼盖具有良好横板向传力性能;板缝连接可有效传递板内弯矩,但正交的两个方向弯矩传递效果存在差异,表现为顺板向弯矩的传递效果优于横板向。研究成果可为分布式连接全装配RC楼盖的研究和应用提供参考。

分布式连接全装配RC楼盖横板向弯曲刚度计算方法研究

在分布式连接全装配RC楼盖(DCNPD)中,板与板之间和梁板之间通过连接件连接以提高楼盖的竖向承载力和平面内刚度。为研究DCNPD竖向承载力计算方法,在试验基础上进行了DCNPD横板向弯曲刚度理论与数值模拟分析。结果表明:DCNPD的竖向承载能力略小于现浇楼盖,远大于不加连接件的装配式楼盖,验证了DCNPD板缝构造横板向传力的有效性;建立了DCNPD横板向弯曲刚度简化分析模型,基于等效梁模型理论提出DCNPD横板向弯曲刚度计算方法,并验证了该方法用于楼盖竖向承载力弹性分析的可行性;楼盖的板缝数和连接件个数对其横板向与整体楼盖的竖向承载能力影响较大,而板缝数的影响更为显著,工程中在运输和吊装条件允许的情况下,宽板预制方案可有效提高楼盖的竖向承载能力。研究成果可为分布式连接全装配RC楼盖的研究应用提供参考和依据。

汶川地震中某RC框架结构的震害分析与模拟

2008年5月12日,四川省汶川县发生里氏8.0级地震,造成了巨大的人员伤亡以及工程结构震害。本文基于江油市某RC框架结构的震害调查,分析了该框架结果出现底层"薄弱层"和"强梁弱柱"的破坏机制的主要原因。采用该框架结构附近三个台站的主震加速度记录作为输入开展了非线性地震反应分析。研究表明,填充墙的竖向不均匀布置改变了框架的抗侧刚度分布,造成底层薄弱层的破坏现象。底层柱子的轴压比相对较大,塑性变形能力及耗能能力相对较差,使得底层柱的变形量更容易达到其塑性变形极限而发生破坏。由于现浇楼板对梁刚度和抗弯承载力的增强,框架结构很难出现规范中"强柱弱梁"的破坏机制。结构基本周期对应的加速度反应谱值是决定结构地震反应的主要参数,基本周期加速度反应谱值的增加会导致结构塑性铰的迅速发展,造成结构出现柱铰机构而整体失稳倒塌。建议设计框架结构时,尽量避免填充墙的不均匀布置。适当增加底层柱的截面面积和配筋率,降低轴压比以保证良好的延性。梁端负向抗弯承载力计算时采用T型截面,并考虑一定范围内楼板配筋的影响。

全装配式RC楼盖板缝节点拉剪复合受力性能试验研究

为研究分布式连接全装配RC楼盖(DCNPD)板缝节点在拉剪复合作用下的受力性能,进行了12个板缝节点在纯剪和拉剪复合作用下受力性能试验,对板缝节点的承载能力、裂缝模式、破坏形态、位移延性和应变规律等进行了较为系统的研究。结果表明:拉力的存在减小了由剪切作用引起的连接件与相邻混凝土间的承压作用,致使板缝节点抗剪承载力不同程度的降低,并且拉剪比越大,拉力对板缝节点屈服荷载和峰值荷载的削弱作用越明显;拉剪复合作用下,板缝节点较早呈现出非线性受力特征;拉力对板缝节点位移延性有较大的削弱,尤其对于楼盖中高拉剪比区域应采取措施避免节点发生脆性破坏;综合考虑板缝节点的荷载-位移响应、位移延性特征和破坏模式等因素,HPC、CPC和HP-CPC三种节点是较为理想的DCNPD板缝节点形式,SPC锚筋与锚板间焊缝在拉剪复合作用下易发生断裂,需改进措施以提高其拉剪复合受力性能。