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Uniaxial stress–strain relationship of concrete confined by various shaped steel tubesKAS Susantha, Hanbin Ge, Tsutomu Usami *Department of Civil Engineering, Nagoya University, Chikusa-ku, Nagoya 464-8603, JapanReceived 31 May 2000; received in revised form 19 December 2000; accepted 14 February 2001AbstractA method is presented to predict the complete stress–strain curve of concrete subjected to triaxial compressive stresses caused by axial load plus lateral pressure due to the confinement action in circular, box and octagonal shaped concrete-filled steel Available empirical formulas are adopted to determine the lateral pressure exerted on concrete in circular concrete-filled steel To evaluate the lateral pressure exerted on the concrete in box and octagonal shaped columns, FEM analysis is adopted with the help of a concrete–steel interaction Subsequently, an extensive parametric study is conducted to propose an empiricalequation for the maximum average lateral pressure, which depends on the material and geometric properties of the Lateral pressure so calculated is correlated to confined concrete strength through a well known empirical For determination of the post-peak stress–strain relation, available experimental results are Based on the test results, approximated expressions to predict the slope of the descending branch and the strain at sustained concrete strength are derived for the confined concrete in columns having each type of sectional The predicted concrete strength and post-peak behavior are found to exhibit goodagreement with the test results within the accepted The proposed model is intended to be used in fiber analysis involving beam–column elements in order to establish an ultimate state prediction criterion for concrete-filled steel columns designed as earthquake resisting •2001 Elsevier Science L All rights Keywords: Concrete-filled tubes; Confinement; Concrete strength; Ductility; Stress–strain relation; Fiber IntroductionConcrete-filled steel tubes (CFT) are becoming increasingly popular in recent decades due to their excellent earthquake resisting characteristics such as high ductility and improved As a result, numerous experimental investigations have been carried out in recent years to examine the overall performance of CFT columns [1–11] Although the behavior of CFT columns has been extensively examined, the concrete core confinement is not yet well Many of the previous research works have been mainly focused on investigating the performance of CFT columns with various The main variables subjected to such limitations were the concrete strength, plate width-to- thickness (or radius-to-thickness) ratios and shapes of the Steel strength, column slenderness ratio and rate of loading were also additionally It is understandable that examination of the effects of all the above factors on performances of CFTs in a wider range, exclusively on experimental manner, is difficult and This can be overcome by following a suitable numerical theoretical approach which is capable of handling many experimentally unmanageable At present, finite element analysis (FEM) is considered as the most powerful and accurate tool to simulate the actual behavior of The accurate constitutive relationships for materials are essential for reliable results when such analysis procedures are For example, CFT behavior may well be investigated through a suitable FEM analysis procedure, provided that appropriate steel and concrete material models are One of the simplest yet powerful techniques for the examination of CFTs is fiber In this procedure the cross section is discretized into many small regions where a uniaxial constitutive relationship of either concrete or steel is This type of analysis can be employed to predict the load–displacement relationships of CFT columns designed as earthquake resisting The accuracy involved with the fiber analysis is found to be quite satisfactory with respect to the practical design At present, an accurate stress–strain relationship for steel, which is readily applicable in the fiber analysis, is currently available [12] However, in the case of concrete, only a few models that are suited for such analysis can be found [3,8,9] Among them, in Tomii and Sakino’s model [3], which is applicable to square shaped columns, the strength improvement due to confinement has been Tang et [8] developed a model for circular tubes by taking into account the effect of geometry and material properties on strength enhancement as well as the post-peak Watanabe et [9] conducted model tests to determine a stress–strain relationship for confined concrete and subsequently proposed a method to analyze the ultimate behavior of concrete-filled box columns considering local buckling of component plates and initial Among the other recent investigations, the work done by Schneider [10] investigated the effect of steel tube shape and wall thickness on the ultimate strength of the composite El-Tawil and Deierlein [11] reviewed and evaluated the concrete encased composite design provisions of the American Concrete Institute Code (ACI 318) [13], the AISC-LRFD Specifications [14] and the AISC Seismic Provisions [15], based on fiber section analyses considering the inelastic behavior of steel and In this study, an analytical approach based on the existing experimental results is attempted to determine a complete uniaxial stress–strain law for confined concrete in relatively thick-walled CFT The primary objective of the proposed stress–strain model is its application in fiber analysis to investigate the inelastic behavior of CFT columns in compression or combined compression and Such analyses are useful in establishing rational strength and ductility prediction procedures of seismic resisting Three types of sectional shapes such as circular, box and octagonal are A concrete–steel interaction model is employed to estimate the lateral pressure on Then, the maximum lateral pressure is correlated to the strength of confined concrete through an empirical A method based on the results of fiber analysis using assumed concrete models is adopted to calibrate the post-peak behavior of the proposed Finally, the complete axial load–average axial strain curves obtained through the fiber analysis using the newly proposed material model are compared with the test It should be noted that a similar type of interaction model as used in this study has been adopted by Nishiyama et [16], which has been combined with a so called peak load condition line in order to determine the maximum lateral pressure on reinforced concrete Meanwhile, previous researches [17,18] indicate that the stress–strain relationship of concrete under compressive load histories produces an envelope curve identical to the stress–strain curve obtained under monotonic Therefore, in further studies, the proposed confined uniaxial stress–strain law can be extended to a cyclic stress–strain relationship of confined concrete by including a suitable unloading/reloading stress–strain Theoretical Characteristic points on confined concrete stress–strain curveReferring to F 1(General stress–strain curves for confined and unconfined ), the following characteristic points have been identified to define a complete stress–strain curve when concrete is confined by surrounding steel The notation in the figure is as follows: f ’c is the strength of unconfined concrete; f ’cc is the strength of confined concrete; εc is the strain at the peak of unconfined concrete; εcc is the strain at the peak of confined concrete; εu is the ultimate strain of unconfined concrete; fu is the ultimate strength of unconfined concrete; εcu is the ultimate strain of confined concrete; and αf ’cc is the residual strength of confined concrete at very high strain The expression for the complete stress–strain curve is defined as suggested by Popovics [19], which was later modified by Mander et [20] and given by where fc and ε denote the longitudinal compressive stress and strain, respectively; Ec stands for the tangent modulus of elasticity of It should be noted that E (1) has been defined even for the post-peak region, in this study, it is utilized only up to the peak The post-peak behavior is treated separately by assuming a linearly varied stress–strain relation as will be discussed in Section 【1-4 F 1】 Confinement action in circular CFT columnsIn short CFT columns with relatively thick-walled sections designed for seismic purposes, failure is mainly caused due to concrete The mode of failure is governed by the individual behavior of each The behavior of concrete in CFT columns under monotonically increasing axial load can be explained in terms of concrete–steel The confinement effect does not exist at the early stage of loading owing to the fact that the Poisson ratio of concrete is lower than that of steel at the initial loading At this level of loading, the circumferential steel hoop stresses are in compression and the concrete is under lateral tension provided that no separation between concrete and steel occurs (, the bond between two materials does not break) However, as the axial load increases, the lateral expansion of concrete gradually becomes greater than the steel due to the change of the Poisson ratio of concrete, and therefore a radial pressure develops at the concrete– steel At this stage, confinement of the concrete core is achieved and the steel is in hoop Load transferring from the steel tube to the concrete occurs at this It is observed that the load at this stage is higher than the sum of loads that can be achieved by steel and concrete acting In the triaxial stress state the uniaxial compressive concrete strength can be given by 【5】 where frp is the maximum radial pressure on concrete and m is an empirical In the past a lot of extensive experimental studies have been carried out to determine a value for coefficient m and it is found that for normal strength concrete, m is in the range of 4–6 [21] In this study m is assumed to be The radial pressure, fr, can be expressed by the relationship given in E (6), which is easily derived by considering the equilibrium of horizontal forces on a circular section: 【6】Here, fsr, t and D denote the circumference stress in steel, the thickness and the outer diameter of the tube, Evaluation of confinement in various shaped CFT Circular sectionDetermination of the confinement level in circular tubes is found in the method proposed by Tang et [8] In this method, the change of the Poisson ratio of concrete and steel with column loading is An empirical factor, β, is introduced for this purpose and subsequently the lateral pressure at the peak load is given by 【7】 Factor β is defined as 【8】 where νe and νs are the Poisson ratios of a steel tube with and without filled-in concrete, Here, νs is taken as equal to 50 at the maximum strength point, and νe is given by the following expressions: 【9 10】 Here, t, D and f ’c are the same as previously defined and fy stands for the yield stress of The above equation is applicable for (f ’c/fy) ranging from 04 to 20 where most of the practically feasible columns are found A detailed description of the method can be found in Tang et [8] It is clear that frp given by E (7) depends on both the material properties and the geometry of the Subsequently, frp calculated from E (7) is substituted into E (5) to determine the confined concrete strength, f ’摘要部分的翻译:各种断面形状钢管混凝土的单轴应力应变关系KAS Susantha , Hanbin Ge, Tsutomu Usami*土木工程学院,名古屋大学, Chikusa-ku ,名古屋 464-8603, 日本收讫于2000年5月31日 ; 正式校定于2000年12月19日; 被认可于2001年2月14日¬¬摘要一种预测受三轴压应力混凝土的完全应力-应变曲线的方法被提出,这种三轴压应力是由环形、箱形和八角形的钢管混凝土中的限制作用导致的轴向荷载加测向压力所产生的。有效的经验公式被用来确定施加于环形钢管混凝土柱内混凝土的侧向压力。FEM(有限元)分析法和混凝土-钢箍交互作用模型已被用来估计施加于箱形和八角形柱的混凝土侧向压力。接着,进行了广泛的参数研究,旨在提出一个经验公式,确定不同的筒材料和结构特性下的最大平均侧向压力。如此计算出的侧向压力通过一个著名经验公式确定出侧向受限混凝土强度。对于高峰之后的应力-应变关系的确定,使用了有效的试验结果。基于这些测试结果,和近似表达式来推算下降段的斜度和各种断面形状的筒内侧向受限混凝土在确认的混凝土强度下的应变。推算出的混凝土强度和后峰值性能在允许的界限内与测试结果吻合得非常好。所提出的模型可用于包括梁柱构件在内的纤维分析,以确定抗震结构设计中混凝土填充钢柱筒的极限状态的推算标准。 •版权所有2001 Elsevier科学技术有限公司。关键词: 钢管混凝土;限制;混凝土强度;延性;应力应变关系;纤维分析这是当年毕业时我的翻译,因为原文有图表等原文也超过10000字,没法在这里发,如需要原文(pdf版及word版)及全部翻译(5000字,中文),请留下邮箱。
Goose tower (大雁塔) The goose tower is located in the Nanjiao greatly kind graciousnesstemple, was the nation famous ancient architecture, is regarded asancient capital Xi'an the After hands down is Tang Sengcongthe India (ancient India) learns from experienced people, specially isengaged in translates after with the Buddhist scriptures Because imitates the Indian wild goose tower style the constructiontherefore the famous wild goose Because afterwards recommendedin the lucky temple in Chang An to construct a smaller wild goosetower, in order to distinguish, the people on called the goose thetower the kind graciousness temple tower, recommended the lucky templetower to call the small wild goose tower, continuously spreads The goose delivers in person the square shape, constructsin side approximately 45 meters, on high approximately 5 meter Tower seven, first floor length of side 25 meters, by place Surface to tower crest elevation 64 The tower bodybecomes with the brickwork, the polished bricks fitting snuglytogether are firm In the tower has the staircase, maycircle Around each respectively has a brige entry, may leanagainst a railing looks out into the The Chang An style getsa panoramic Around the tower first floor all has Shimen, on thegate mast has the fine line to engrave the image of Buddha, passes onfor the Tang Dynasty big painter Yan Liben writing In the towerNanmen two sides brick niches, inlays has Tang fourth day of a soldierthen good book storytelling legalist schools big tang dynasty pilgrimmonk saint to teach the foreword "and" States Tripitaka Saint To teachForeword To record "two After Tang Mo, the temple repeatedlysays the warfare, the palace burns d
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