不卸载时侧贴碳纤维布加固连续梁试验研究

为研究不同初始荷载作用下侧贴碳纤维布加固连续梁的受力与变形特性,以及初始荷载对加固效果的影响,对4根钢筋混凝土两跨连续梁（其中1根为未加固连续梁,其余3根为在不同初始荷载下侧贴碳纤维布加固连续梁）进行了试验研究。结果表明：侧贴碳纤维布加固连续梁不仅能提高加固梁的承载力,提高幅度达16%以上;还能提高加固梁的刚度,减少其挠度和裂缝宽度;加固效果受初始荷载影响,初始荷载越小,加固效果越好。     

预应力CFRP筋T形梁受弯性能试验及变形分析

试验通过对3根T形预应力CFRP筋混凝土梁和1根矩形预应力CFRP筋混凝土梁进行对比,考察了预应力CFRP筋混凝土梁的受弯工作性能,记录了试验梁的开裂荷载、极限荷载和裂缝发展情况。试验结果表明：增加预应力度和总配筋率对提高开裂荷载,限制挠度、裂缝发展起重要作用;相同配筋的T形梁和矩形梁挠度相近,但各阶段荷载不同。对预应力CFRP筋T形梁的变形性能进行了理论分析,推导了短期荷载作用下刚度和挠度的计算公式,并将计算值与试验值进行比较,两者吻合良好。     

侧贴碳纤维布加固连续梁非线性有限元分析

为研究不同初始荷载作用下侧贴碳纤维布及侧贴预应力碳纤维布加固钢筋混凝土连续梁的加固效果,采用有限元分析软件ABAQUS对其进行数值模拟,并将有限元分析结果与试验结果对比。有限元分析表明：钢筋混凝土连续梁的加固效果受初始荷载的影响,初始荷载越小,加固效果越好;对纵向侧贴碳纤维布施加预应力,能够大幅提高钢筋混凝土连续梁的抗弯承载力,与未加固梁相比其抗弯承载力提高了65%以上;有限元计算结果与试验结果的荷载-挠度曲线吻合较好,两者的抗弯承载力相差不超过10%。所得结果可以为类似加固设计和试验提供参考。     

先张预应力BFRP筋混凝土梁受弯性能试验研究

玄武岩纤维筋是一种新型复合材料,具有轻质、高强、非磁性、耐高温、耐酸碱等多重优点.完成了直径为10 mm的BFRP筋基本力学性能测试.进行了3根先张有粘结预应力BFRP筋混凝土梁,1根非预应力BFRP筋混凝土梁的受弯性能对比试验,分析了试验梁受力过程及破坏形态、平截面假定情况、特征荷载值、荷载--挠度关系、裂缝发展情况...     

新型BFRP筋增强混凝土受弯构件挠度控制

玄武岩纤维塑料增强筋（BFRP筋）的特性导致以其为增强筋的受弯构件出现裂缝后刚度降低非常明显,变形发展过快。因此,对BFRP筋混凝土梁的设计主要应根据其变形性能标准的要求来进行。为方便设计人员进行BFRP筋受弯构件设计,结合试验研究,通过对比国内外有关FRP筋混凝土梁开裂截面有限惯性矩计算模型的研究,探索出适合BFRP筋混凝土梁开裂截面有效惯性矩计算模型;通过建模分析,表明有限元计算模型和其他几种计算模型一起可以应用于BFRP筋混凝土梁直接挠度控制。推导出FRP筋受弯构件配筋率计算公式,结合直接挠度控制研究,提出通过控制跨高比限值来进行梁尺寸初选的间接挠度控制计算公式。     

体内芳纶纤维筋梁受弯性能试验研究分析

通过钢筋混凝土梁与芳纶纤维筋梁的弯曲试验现象和结果,探讨了芳纶纤维筋梁的正截面受力性能和破坏模式,分析了芳纶纤维筋配筋率对混凝土梁的裂缝宽度、挠度和承载力等的影响,为今后进一步研究和设计AFRP筋受弯构件提供了参考。     

BFRP连续螺旋箍筋混凝土梁抗剪性能试验研究

为研究BFRP连续螺旋箍筋的抗剪性能,设计制作了6根配置BFRP连续螺旋箍筋的混凝土梁和2根配置矩形连续螺旋钢箍的对比混凝土梁.通过试验,得出了BFRP连续螺旋箍筋混凝土梁的抗剪性能,分析了配箍率、剪跨比和纵筋率等因素对构件抗剪性能的影响:构件的受剪破坏模式分为斜拉破坏和斜压破坏两种类型;在不同的受剪破坏模式下,斜裂缝...     

玄武岩纤维增强塑料筋耐海水腐蚀性研究

海工工程中由于海水的腐蚀,混凝土中的钢筋会出现锈蚀等问题.玄武岩纤维增强塑料筋作为一种新型建筑材料,用来代替钢筋用在海工工程等腐蚀性较强的混凝土中,以此避免钢筋锈蚀带来的耐久性问题.研究了玄武岩纤维增强塑料筋耐海水腐蚀性,采用常温长期浸泡和高温浸泡加速腐蚀试验方法,得出玄武岩纤维增强塑料筋在常温下耐海水腐蚀性较强,而在...     

CFRP加固混凝土柱抗震性能的有限元分析

为验证CFRP抗震加固方法的有效性,通过介绍其抗震加固的机理,利用有限元软件ANSYS模拟轴向压力与单向及双向地震往复荷载耦合作用下其加固混凝土柱的抗震性能,并与未加固柱进行对比,论证了其对混凝土柱抗震性能提高的有效性,从而为试验及加固工程施工提供了有效的理论分析方法。     

有粘结预应力BFRP筋混凝土梁受弯性能理论研究

玄武岩纤维筋是一种新型复合材料,在国防和特殊建筑工程领域具有重要的应用价值.对不同预应力度的3根有粘结预应力BFRP筋混凝土试验梁进行理论研究,初步探讨和建立预应力BFRP筋混凝土梁的破坏模式判别、正截面受弯承载力、短期刚度、平均裂缝间距、平均裂缝宽度的计算方法,理论计算值与试验结果吻合较好,为建立新型预应力BFRP筋...     

Blast resistance evaluation of urban utility tunnel reinforced with BFRP bars

To improve corrosion-resistance of shallow-buried concrete urban utility tunnels(UUTs),basalt fiber reinforced polymer(BFRP)bars are applied to reinforce UUTs.As the UUT must have excellent survival capability under accidental explosions,a shallow-buried BFRP bars reinforced UUT(BBRU)was designed and constructed.Repetitive blast experiments were carried out on this BBRU.Dynamic responses,damage evolutions and failure styles of the BBRU under repetitive explosions were revealed.The tunnel roof is the most vulnerable component and longitudinal cracks develop along the tunnel.When the scaled distance is larger than 1.10 m/kg1/3,no cracks are observed in the experiments.When the BBRU is severely damaged,there are five cracks forming and developing along the roof.The roof is simplified as a clamped-supported one-way slab,proved by the observation that the maximum strain of the transverse bar is much larger than that of the longitudinal bar.Dynamic responses of the roof slab are predicted by dynamic Euler beam theory,which can consistently predict the roof displacement under large-scaled-distance explosion.Compared with the UUT reinforced with steel bars,the BBRU has advantages in blast resistance with smaller deflections and more evenly-distributed cracks when the scaled distance is smaller than 1.260 m/kg1/3 and the steel bars enter plastic state.Longer elastic defamation of the BFRP bars endows the UUT more excellent blast resistance under small-scaled-distance explosions.     

Experimental investigation on dynamic response and damage models of circular RC columns subjected to underwater explosions

Reinforced concrete (RC) columns are widely used as supporting structures for high-piled wharfs. The study of damage model of a RC column due to underwater explosion is a critical issue to assess the wharf’s antiknock security. In this study, the dynamic response and damage model of circular RC columns subjected to underwater explosions were investigated by means of scaled-down experiment models. Experiments were carried out in a 10.0 m diameter tank with the water depth of 2.25 m, under different explosive quantities (0.025 kg–1.6 kg), stand-off distances (0.0 m–7.0 m), and detonation depths (0.25 m–2.0 m). The shock wave load and dynamic response of experiment models were measured by configuring sensors of pressure, acceleration, strain, and displacement. Then, the load distribution characteristics, time history of test data, and damage models related to present conditions were obtained and discussed. Three damage models, including bending failure, bending-shear failure and punching failure, were identified. In addition, the experience model of shock wave loads on the surface of a RC column was proposed for engineering application.     

体外预应力FRP片材加固混凝土结构的研究现状及发展

CFRP片材加固混凝土梁是一种新型的加固方法,但该方法存在着CFRP强度利用不高、对梁使用阶段性能改善不明显等问题,对CFRP施加预应力,不仅可以充分利用CFRP的强度,还能有效地改善加固梁的受力性能,进一步抑制梁的变形和裂缝的开展。体外预应力FRP片材加固混凝土结构近几年来在国外得到了广泛的研究与应用。对在该领域已有的研究成果从预应力的施工工艺、张拉控制应力、锚固措施、预应力损失和设计方法等方面进行了总结,可为今后开展相关的研究和应用提供借鉴和参考。     

Responses of HFR-LWC beams under close-range blast loadings accompanying membrane action

The load-carrying capacities and failure patterns of reinforced concrete components can be significantly changed by membrane effects. However, limited work has been carried out to investigate the blast resistance of Hybrid Fiber Reinforced Lightweight Aggregate Concrete (HFR-LWC) members accompanying membrane action. This paper presents a theoretical approach to quantitatively depicting the membrane behavior and its contribution on the behavior of HFR-LWC beams under close-range blast loadings, and the suitability of the proposed model is validated by a series of field tests. An improved Single-Degree-of-Freedom (SDOF) model was employed to describe the dynamic responses of beam-like members under blast loadings accompanying membrane action, where the mass-load coefficient is determined according to the nonuniformly distributed load induced by close-range explosion, and the membrane action is characterized by an in-plane (longitudinal) force and a resisting moment. The elasto-plastic and recovery responses of HFR-LWC beams under the combined action of blast load and membrane force were analyzed by the promoted model. A specially built end-constrain clamp was developed to provide membrane action for the beam member when they are subjected to blast load simultaneously. It is demonstrated that the analytical displacement-time histories are in good agreement with experimental results before peak deflections and that the improved SDOF model is an acceptable tool for predicting the behavior of HFR-LWC beams under blast loadings accompanying membrane action.     

Investigation of the mechanical and ballistic properties of hybrid carbon/ aramid woven laminates

High-performance ballistic fibers, such as aramid fiber and ultra-high-molecular-weight polyethylene (UHMWPE), are commonly used in anti-ballistic structures due to their low density, high tensile strength and high specific modulus. However, their low modulus in the thickness direction and insufficient shear strength limits their application in certain ballistic structure. In contrast, carbon fiber reinforced epoxy resin matrix composites (CFRP) have the characteristics of high modulus in the thickness direction and high shear resistance. However, carbon fibers are rarely used and applied for protection purposes. A hybridization with aramid fiber reinforced epoxy resin matrix composites (AFRP) and CFRP has the potential to improve the stiffness and the ballistic property of the typical ballistic fiber composites. The hybrid effects on the flexural property and ballistic performance of the hybrid CFRP/AFRP laminates were investigated. Through conducting mechanical property tests and ballistic tests, two sets of reliable simulation parameters for AFRP and CFRP were established using LS-DYNA software, respectively. The experimental results suggested that by increasing the content of CFRP that the flexural properties of hybrid CFRP/AFRP laminates were enhanced. The ballistic tests’ results and the simulation illustrated that the specific energy absorption by the perforation method of CFRP achieved 77.7% of AFRP. When CFRP was on the striking face, the shear resistance of the laminates and the resistance force to the projectiles was promoted at the initial penetration stage. The proportion of fiber tensile failures in the AFRP layers was also enhanced with the addition of CFRP during the penetration process. These improvements resulted in the ballistic performance of hybrid CFRP/AFRP laminates was better than AFRP when the CFRP content was 20 wt% and 30 wt%.     

带裂缝钢筋混凝土梁振动特性变刚度模型分析

按常规等刚度、匀质线性材料来考虑开裂后的钢筋混凝土梁,必然带来较大的误差,与实际情况存在较大差距。基于条带法提出了建立带裂缝钢筋混凝土梁的变刚度模型分析方法,对考虑开裂和材料非线性的钢筋混凝土简支梁的振动特性进行了理论计算和试验研究。结果表明：提出的方法从理论上可以得到既有钢筋混凝土简支梁的振动特性、裂缝开展情况等参数,理论计算结果与试验结果吻合较好,且精度较高,具有良好的可行性和工程适用性。     

预应力与非预应力BFRP筋混凝土梁非线性有限元分析

玄武岩纤维筋（BFRP筋）是一种性能优良的新型复合材料。为研究玄武岩纤维筋在预应力结构中的应用,运用混凝土结构非线性有限元的基本理论,利用ANSYS对预应力、非预应力玄武岩纤维筋混凝土梁进行非线性全过程计算。根据荷载挠度曲线、特征荷载值、裂缝情况等结果进行对比分析,结果表明预应力玄武岩纤维筋混凝土梁具有较高的抗裂度和刚度,而变形能力却较差;在等配筋率的情况下,极限承载力与非预应力梁相当。     

土工格栅加筋土挡墙稳定性影响因素敏感性分析

以灰关联分析法为手段,通过有限元强度折减法计算加筋土挡墙的稳定安全系数。结合水富—麻柳湾高速公路的土工格栅加筋土挡墙实际工程,分析了各因素对土工格栅加筋土挡墙稳定影响的敏感性,按大小依次为：内摩擦角、筋土间摩擦系数、粘聚力、筋带长度、筋带轴向拉伸刚度、筋带间距和填土密度。建议设计中,如果条件许可应优先选择摩擦角和粘聚力较高的填料,当填料受限制时,要提高加筋土挡墙的稳定性可以优先考虑选择与填土有较高摩擦系数和轴向拉伸刚度较大的土工格栅进行设计。     

分段轴压阶梯梁自由振动及稳定性分析的传递函数方法

采用分布传递函数方法,分析任意多段分段常轴压阶梯梁的自由振动和稳定问题,得到形式统一的封闭解析解。根据梁横截面几何尺寸、梁材料和轴压沿梁轴线的变化,将梁分成多段子梁,对每一子梁采用传递函数方法得到其解析解,通过各子梁间的位移连续和力平衡条件,得到分段常轴压阶梯梁的各阶自由振动频率和失稳载荷及其相应的模态形状。通过三阶梯梁的算例验证本文方法的正确性,并以四阶梯梁为例,计算分段轴压多阶梯梁自由振动的固有频率。     

基于ANSYS的预应力CFRP布加固混凝土梁有限元分析

采用ANSYS有限元分析软件,对卸载或不卸载时预应力碳纤维(CFRP)布加固梁进行仿真分析,并在有限元分析中提出了施加预应力的方法(升温法),以及利用单元的生与死实现不卸载时加固的方法。通过实例对比分析表明,基于ANSYS的有限元分析结果与试验分析结果吻合较好,可在一定程度上有效替代试验分析方法,从而减少试验所需的时间和费用,对后续的CFRP布加固混凝土结构的研究工作具有一定的参考价值。