Mechanics Behavior of Ultra High Toughness Cementitious Composites after Freezing and Thawing

Mechanical behaviors of UHTCC after freezing and thawing were investigated,and compared with those of steel fiber reinforced concrete（SFRC）,air-entrained concrete（AEC） and ordinary concrete（OC）.Four point bending tests had been applied after different freezing-thawing cycles（0,50,100,150,200 and 300 cycles,respectively）.The results showed that residual flexural strength of UHTCC after 300 freezing-thawing cycles was 10.62 MPa（70% of no freezing thawing ones）,while 1.58 MPa（17% of no freezing thawing ones） for SFRC.Flexural toughness of UHTCC decreased by 17%,while 70% for SFRC comparatively.It has been demonstrated experimentally that UHTCC without any air-entraining agent could resist freezing-thawing and retain its high toughness characteristic in cold environment.Consequently,UHTCC could be put into practice for new-built or retrofit of infrastructures in cold regions.

Preparation of Self-compacting Ultra-high Toughness Cementitious Composite

A self-compacting ultra-high toughness cementitious composite （UHTCC） reinforced by discontinuous short polyvinyl alcohol （PVA） fibers, which exhibits self-compacting performance in the fresh state and strain-hardening and multiple cracking behavior in the hardened state, was developed through controlling flow properties of fresh mortar matrix at constant ingredients concentrations determined by micromechanical design and ensuring uniform fibers dispersion. The superplasticizer was utilized to adjust its flow properties in the fresh state. A series of flow tests, including deformability test, flow rate test, and self-placing test, were conducted to characterize and quantify the fluidity performance of fresh mortar matrix and self-compactability of fresh UHTCC. It is revealed that the utilization of superplasticizer is efficient in producing the fresh mortar matrix with desirable fluidity and the resulting self-compacting UHTCC. In addition, results of four point bending tests on the developed self-compacting UHTCC confirm the insensitivity of mechanical performance of self-compacting UHTCC to the presence of external vibrations as well as the flexural characteristics of deformation hardening and multiple cracking.

Uniaxial Compressive Properties of Ultra High Toughness Cementitious Composite

Uniaxial compression tests were conducted to characterize the main compressive performance of ultra high toughness cementitious composite （UHTCC） in terms of strength and toughness and to obtain its stress-strain relationships. The compressive strength investigated ranges from 30 MPa to 60 MPa. Complete stress-strain curves were directly obtained, and the strength indexes, including uniaxial compressive strength, compressive strain at peak stress, elastic modulus and Poisson＇s ratio, were calculated. The comparisons between UHTCC and matrix were also carried out to understand the fiber effect on the compressive strength indexes. Three dimensionless toughness indexes were calculated, which either represent its relative improvement in energy absorption capacity because of fiber addition or provide an indication of its behavior relative to a rigid-plastic material. Moreover, two new toughness indexes, which were named as post-crack deformation energy and equivalent compressive strength, were proposed and calculated with the aim at linking up the compressive toughness of UHTCC with the existing design concept of concrete. The failure mode was also given. The study production provides material characteristics for the practical engineering application of UHTCC.

Direct tension and fracture resistance curves of ultra high performance marine composite materials

Fracture behavior is one of the most important,yet still little understood properties of ultra-high performance cementitious composites(UHPCC),a new marine structural engineering material. Research on the fracture and direct tension behavior of UHPCC was carried out.The constitution law of UHPCC was divided into three phases:pre-partial debonding,partial debonding,and pullout phases.A direct tension constitution law was constructed based on the proposed fiber reinforcing parameter as a function of fiber volume fraction,fiber diameter and length,and fiber bonding strength.With the definition of linear crack shape,the energy release rate of UHPCC was derived and the R-curve equation was calculated from this.Loading tests of UHPCC using a three-point bending beam with an initial notch were carried out.The predictions from the proposed R-curve were in good agreement with the test results, indicating that the proposed R-curve accurately describes the fracture resistance of UHPCC.Introduction of a fiber reinforcement parameter bridges the fracture property R-curve and micro-composites’ mechanics parameters together.This has laid the foundation for further research into fracture properties based on micro-mechanics.The proposed tension constitution law and R-curve can be references for future UHPCC fracture evaluation.

Dynamic damage and stress-strain relations of ultra-high performance cementitious composites subjected to repeated impact

Ultra-high performance cementitious composites (UHPCC) were prepared by replacing 60% of cement with ultra-fine industrial waste powders.The dynamic damage and compressive stress-strain relations of UHPCC were studied using split Hopkinson pressure bar (SHPB).The damage of UHPCC subjected to repeated impact was measured by the ultrasonic pulse velocity method.Results show that the dynamic damage of UHPCC increases linearly with impact times and the abilities of repeated impact resistance of UHPCC are improved with increasing fiber volume fraction.The stress waves on impact were recorded and the average stress,strain and strain rate of UHPCC were calculated based on the wave propagation theory.The effects of strain rate,fibers volume fraction and impact times on the stress-strain relations of UHPCC were studied.Results show that the peak stress and elastic modulus decrease while the strain rate and peak strain increase gradually with increasing impact times.

钢-UHPC组合桥面板横向负弯矩区受弯性能研究

为明确横向负弯矩作用下,剪力键形式、接缝设置情形、配筋率和钢混界面黏结状态等参数对钢-超高性能混凝土(ultra-high-performance concrete,UHPC)组合板受力性能的影响,完成了8块组合板局部足尺模型静力弯曲试验及有限元参数分析。试验结果表明:开孔板(perfobond leiste,PBL)试件的名义开裂强度(对应最大裂缝宽度为0.05 mm)较栓钉试件提高16.8%;矩形齿缝试件的名义开裂强度较整浇试件降低16%~23%;UHPC层钢筋配筋率从1.96%增加到2.82%时,名义开裂强度提高16.2%;钢板-UHPC界面涂油除黏PBL试件的初裂强度和名义开裂强度较界面黏结试件分别降低10.1%和5.8%。数值分析结果表明:PBL贯穿钢筋的存在、PBL和栓钉间距的减小能有效提高组合板的开裂后刚度;PBL开孔钢板上的孔径和孔间距对组合板的受力性能影响较小。

部分充填式窄幅钢箱-UHPC组合梁抗裂性能

为研究部分充填式窄幅钢箱-UHPC组合梁的抗裂性能,开展了4根不同钢纤维掺量的部分充填式窄幅钢箱-UHPC组合梁与1根部分充填式窄幅钢箱-NC组合梁静力加载试验。试验表明:在负弯矩作用下,部分充填式窄幅钢箱-UHPC组合梁裂缝呈现数量多、短小且密集的特点;同等配筋率的条件下,不同钢纤维掺量(0、1%、2%和3%)部分充填式窄幅钢箱-UHPC组合梁与部分充填式窄幅钢箱-NC组合梁相比,在弹性阶段其刚度明显提高,最大裂缝宽度随钢纤维掺量的增加而减少,开裂强度分别提高了36.0%、48.8%、82.0%和112.0%,UHPC显著提高了组合梁的抗裂性能;可以参考按照JTG 3362—2018中裂缝宽度式乘以0.8的修正系数来计算部分充填式窄幅钢箱-UHPC组合梁裂缝宽度。

钢-薄层UHPC组合桥面结构中PBL剪力键抗剪性能试验

为探究钢-超高性能混凝土(UHPC)组合桥面结构中PBL剪力键的抗剪性能,以抗剪钢板尺寸、贯穿钢筋设置和端部承压状态为试验参数,完成了16个PBL试件的推出试验。结果表明:(1)随着抗剪钢板尺寸的增加,试件由UHPC榫无明显损伤时的钢板剪断破坏转变为UHPC榫局部压碎或整体压碎后的钢板剪断破坏,PBL的极限承载力随之相应提高,但其延性系数无明显变化;(2)贯穿钢筋对PBL承载能力的影响与UHPC榫的损伤状态密切相关,其对PBL抗剪承载能力的提高由榫无明显损伤时的5.3%增加到榫局部压碎时的9.7%和榫整体压碎时的14.9%;(3)对于钢-UHPC组合桥面结构中平行阵列布置的多列PBL,当列间距不小于10倍贯穿钢筋直径或12倍抗剪钢板厚度时,相邻列剪力键间相互作用的影响较小。基于试验结果,提出了适用于组合桥面结构中PBL剪力键的抗剪承载力计算公式,并以本文及其它文献的试验结果验证了其适用性。

A dynamic constitutive model of ultra high toughness cementitious composites

In this study,an explicit dynamic constitutive model was established for ultra high toughness cementitious composites(UHTCCs).The model,based on the Holmquist–Johnson–Cook(HJC)model,includes tensile and compressive damage evolution,hydrostatic pressure,strain rate,and the Lode angle effect.The proposed model was embedded in LS-DYNA software and then comprehensive tests were carried on a hexahedral brick element formulation under uniaxial,biaxial,and triaxial stress states to verify its rationality through comparisons with results determined by the HJC and Karagozian&Case(K&C)models.Finally,the proposed model was used to simulate the damage caused to UHTCC targets subjected to blast by embedded explosive and projectile penetration,and predictions were compared with corresponding experimental results.The results of the numerical simulations showed that our proposed model was more accurate than the HJC model in predicting the size of the crater,penetration depth,and the distribution of cracks inside the target following the blast or high-speed impact loading.

UHPC-RC节段组合梁的抗弯性能分析

为研究低预应力度条件下,不同节段接缝的超高性能混凝土-钢筋混凝土(ultra-high performance concrete-reinforced concrete,UHPC-RC)组合梁的抗弯性能,文章基于ABAQUS有限元软件,建立UHPC-RC节段组合梁的基准有限元模型,并利用已有的试验数据验证该模型的合理性。节段接缝分别为平面干接缝、平面胶接缝、齿键干接缝和齿键胶接缝,在基准有限元模型的基础上,进一步研究节段接缝类型对组合梁抗弯性能的影响。研究发现,在四点受弯加载方式下,接缝的几何特征(平面或齿键)对组合梁的极限荷载和开裂荷载影响较小,环氧树脂胶的使用对组合梁的抗弯性能影响较大。

负弯矩区部分充填式窄幅钢箱-UHPC-NC组合梁抗剪承载力研究

为研究部分充填式窄幅钢箱-UHPC-NC组合梁负弯矩区受剪性能,开展3根部分充填式窄幅钢箱组合梁加载试验,研究组合梁的破坏模式、变形及裂缝分布规律。基于ABAQUS软件建立组合梁有限元模型,通过试验结果验证模型的准确性,并分析充填混凝土强度fcu、充填混凝土高度hf、UHPC层厚度hu和剪跨比λ对组合梁抗剪承载力的影响。研究结果表明:3根组合梁钢箱上箱室均发生剪切破坏,翼板跨中出现弯曲主裂缝,加载点与支座间产生剪切斜裂缝。在弹性阶段,UHPC和NC、钢箱与翼板协同工作性能良好,NC翼板组合梁端部表现出明显的剪切破坏;UHPC翼板组合梁的开裂荷载、屈服荷载及极限荷载较NC翼板组合梁分别提高55%、37.5%和12.5%,最大裂缝宽度从1.48 mm降至0.82 mm。有限元模型计算与试验结果吻合良好,可用于组合梁受力性能参数分析。组合梁抗剪承载力随hu的增加基本呈线性关系,当hu从0增加至100 mm时,组合梁抗剪承载力提高12.5%;当hf达到0.3后、提高fcu对组合梁抗剪承载力的影响并不显著,hf应控制在0.3左右且fcu不宜过高;组合梁抗剪承载力随着λ的增加基本呈线性关系递减,λ=2.8为组合梁弯剪破坏和受弯破坏界限剪跨比。提出考虑钢箱、充填混凝土和翼板贡献的组合梁抗剪承载力计算公式,并与试验和数值模拟结果进行验证分析,结果吻合良好且偏于安全。

粗骨料对超高性能应变硬化水泥基复合材料(UHP-SHCC)性能的影响

根据超高性能混凝土(UHPC)的制备理论和应变硬化水泥基复合材料(SHCC)的设计原理,制备了超高性能应变硬化水泥基复合材料(UHP-SHCC),研究了钢纤维改性处理和粗骨料的级配(最大粒径分别为6.00、8.00、9.75 mm)与掺量(0、5%、11%、15%)对UHP-SHCC抗压强度和拉伸行为的影响。结果表明:与未改性钢纤维相比,改性钢纤维使UHP-SHCC的应变硬化行为更明显;通过合理调控粗骨料的级配和掺量,有效提高了UHP-SHCC的抗压强度,改善了UHP-SHCC的拉伸应变硬化效果,但随着龄期从7 d增至28 d,UHP-SHCC的应变硬化效果略有减弱。

超高性能混凝土-充填式窄幅钢箱组合梁裂缝宽度计算

为了探讨超高性能混凝土-充填式窄幅钢箱组合梁裂缝发展规律和分布,评估现行规范中最大裂缝宽度计算公式对该类组合梁的适用性,考虑组合梁钢纤维掺量、充填混凝土高度和配筋率3个因素,对6根该类组合梁开展弯曲试验;根据超高性能混凝土的特性,提出该类组合梁钢筋应力计算方法;修正现行规范中最大裂缝宽度计算公式,并考虑钢纤维掺量的影响,建立该类组合梁的最大裂缝宽度计算公式。结果表明:组合梁开始出现裂缝后最大裂缝宽度发展较缓慢,在最大裂缝宽度达到0.16 mm之前,荷载等级-最大裂缝宽度曲线大致呈线性,组合梁屈服后裂缝宽度迅速增大;增加钢纤维掺量和配筋率可明显限制裂缝发展,钢箱充填超高性能混凝土可明显增强组合梁极限承载能力;现行规范中最大裂缝宽度公式计算该类组合梁最大裂缝宽度过于保守,所提出该类组合梁钢筋应力计算方法和组合梁最大裂缝宽度公式的计算值与弯曲试验实测值均吻合较好。

水烛香蒲与无苞香蒲化学成分的超高效液相色谱-四极杆飞行时间质谱检测分析

目的对水烛香蒲花粉和无苞香蒲的花粉和茎叶中化学成分进行分析,以期探讨香蒲属植物化学成分差异。方法于2022年5—10月,对从南京市建邺区江心洲采集到的两种蒲黄进行了分析。首先通过扫描电镜对两种蒲黄花粉进行显微鉴定,其次采用超高效液相色谱-四极杆飞行时间质谱(UPLC-Q-TOF-MS/MS)进行分析,色谱条件为ACQUITYTM UPLC HSS T3柱(100 mm×2.1 mm,1.8μm),以0.1%甲酸水溶液和乙腈为流动相,梯度洗脱,流速0.3 mL/min,柱温30℃,进样量4μL。通过已知对照品、质谱及文献对化合物进行化学成分分析。结果鉴定出来的两种香蒲分别是水烛香蒲和无苞香蒲。花粉及茎叶中共解析出58个化合物,包含黄酮类27个,有机酸类19个,有机酮类3个,有机酯类3个,聚酮类1个,氨基酸类1个,酰胺类1个,有机醇类1个,苯类1个以及核苷类1个,其中的21个化合物在两种香蒲之间有差异,花粉与茎叶之间也有明显差异,但花粉中黄酮类成分差异不大。结论UPLC-Q-TOF-MS/MS测定方法简便、重现性好,为蒲黄的临床用药与质量标准的建立利用提供了科学依据。

基于超高效液相色谱-串联质谱检测三黄膏主要成分

目的:采用超高效液相色谱-串联质谱(Ultra Performance Liquid Chromatography-Tandem Mass Spectrometry,UPLC-MS/MS)对三黄膏的化学成分进行分析和鉴定。方法:取三黄膏50 mg加入甲醇内标提取液,涡旋后取上清液,用微孔滤膜过滤后准备检测。液相条件:Agilent SB-C18 1.8μm,2.1 mm×100 mm色谱柱,以超纯水(加入0.1%的甲酸)和乙腈(加入0.1%的甲酸)为流动相,梯度洗脱,流速0.36 mL/min,柱温40℃,进样量2μL。质谱条件:电喷雾离子源温度500℃;离子喷雾电压5 500 V(正离子模式)/–4 500 V(负离子模式);离子源气体I(GSI)、气体II(GSII)和气帘气分别设置为50、60和25 psi,碰撞诱导电离参数设置为高。三重四级杆扫描使用多反应检测(Multiple Reaction Monitoring,MRM)模式,并将碰撞气体(氮气)设置为中等。通过进一步的去簇电压(Declustering Potential,DP)和碰撞能(Collision Energy,CE)优化,完成了各个MRM离子对的DP和CE。根据每个时期内洗脱的代谢物,在每个时期监测一组特定的MRM离子对。采用电喷雾离子源,正负离子模式下采集数据。结果:共鉴定和推测出30个化合物,包括11种生物碱类、11种黄酮类、3种萜类、5种酚酸类。结论:通过UPLC-MS/MS鉴定的30种化合物与黄芩、黄连、黄柏主要化合物进行对比后发现,经过加工处理后的三黄膏保留了黄芩、黄连、黄柏的主要化学成分。为今后三黄膏的物质基础研究奠定了基础。

可拆卸式钢-预制UHPC组合梁中高强螺栓剪力键的抗剪性能试验

试验共设计16个推出试件,探究螺栓直径、螺栓等级、螺栓预紧力和剪力键类型对钢-预制超高性能混凝土(ultra-high performance concrete,UHPC)组合梁中高强螺栓剪力键抗剪性能的影响.试验结果表明,推出试件以剪力键剪断为主要破坏模式.螺栓剪力键的抗剪性能随螺栓的直径和螺栓等级的增大而提高;螺栓预紧力仅对初始抗剪刚度有影响;相比于传统焊钉剪力键,螺栓剪力键的单栓抗剪承载力有所下降,但整体抗剪性能仍满足结构性能要求.结合试验结果和国内外规范公式,提出一条更精确的计算公式用以预测钢-预制UHPC组合梁中螺栓剪力键的抗剪承载力.

采用装配式栓钉的钢-UHPC组合板的抗弯性能

为提高钢-UHPC组合结构的延性,本文提出一种采用装配式栓钉连接的钢-UHPC组合板。设计并完成了不同抗剪连接程度的组合板的抗弯性能试验,分析了组合板试件破坏形态、极限承载力、刚度、裂缝发展规律和板端滑移,并与采用焊接栓钉的钢-UHPC组合板进行了对比分析,讨论了组合板试件的可拆卸性,最后对其极限抗弯承载力和抗弯刚度进行了理论分析并推导了计算公式。结果表明:装配式栓钉连接的钢-UHPC组合板破坏模式为纵向水平剪切黏结破坏;降低栓钉间距能提高组合板的协同变形能力,从而提高组合板结构的极限承载力、弹塑性阶段的刚度和裂缝控制能力;与采用焊接栓钉连接的钢-UHPC组合板对比,其在发生较大变形的情况下钢板和UHPC板仍然可较容易地拆卸分离;推导了装配式栓钉连接的钢-UHPC组合板的极限承载力计算方法和抗弯刚度计算公式,提出了抗弯刚度计算时应对UHPC板高度进行折减,折减系数(βU)在正常使用阶段建议为0.85,理论计算结果与试验结果吻合良好。本文研究成果可为采用装配式栓钉的钢-UHPC组合板的设计和应用提供理论依据。

复合免疫亲和柱净化-超高效液相色谱-串联质谱法测定衢枳壳中5种真菌毒素的含量

提出了题示方法测定衢枳壳样品中黄曲霉毒素B1、B2、G1、G2和赭曲霉毒素A的含量。样品经过体积比79∶20∶1的乙腈-水-乙酸混合溶液超声提取,离心,上清液用p H 7.0磷酸盐缓冲液稀释,用复合免疫亲和柱净化,过滤,滤液中的目标物在XDB C18色谱柱上用不同体积比的体积比1∶9的甲醇-5 mmol·L^(-1)乙酸铵混合溶液和体积比9∶1的甲醇-5 mmol·L^(-1)乙酸铵混合溶液的混合溶液分离,电喷雾离子源正离子(ESI+)和多反应监测(MRM)模式检测,同位素内标法定量。结果显示:5种真菌毒素与其同位素内标质量浓度比和对应的峰面积比在一定范围内呈线性关系,检出限为0.05~0.20μg·kg^(-1)。3个加标浓度水平下阴性样品中5种真菌毒素的回收率为82.7%~97.3%,测定值的相对标准偏差(n=6)为5.2%~12%。

UHPC-NC组合箱梁顶板界面抗剪性能试验研究

为了研究超高性能混凝土(UHPC)与普通混凝土(NC)组合箱梁的界面抗剪性能,该文设计了3类界面处理方式不同的试件,分别为不处理类、凿毛类、涂缓凝剂+水冲洗类,同时进行了UHPC与NC的组合推出试验,分析3类试件的破坏形态和抗剪性能.试验结果表明:UHPC与NC组合结构进行界面处理后,推出试件的破坏形态为普通混凝土侧的拔出破坏,与界面不处理的破坏形态相同,且各类试件的初始剪切刚度相近.但不同界面处理方式对试件的平均抗剪强度影响较大,进行界面处理后相较于不处理时的平均抗剪强度大幅提高,均为不处理时的4倍以上.

基于金属有机骨架材料复合气凝胶的分散固相萃取-超高效液相色谱-串联质谱法测定水中7种苯氧羧酸类除草剂

苯氧羧酸类除草剂(PCAs)在水体中难以降解,对人类健康和生态环境造成严重威胁,因此亟需建立有效测定水体中痕量PCAs的方法。本文以常温干燥法制备的金属有机骨架/海藻酸钠气凝胶材料MIL-101(Fe)-NH 2/SA作为分散固相萃取的吸附剂,对环境水体中的7种PCAs进行吸附和富集,从萃取条件(气凝胶中MIL-101(Fe)-NH 2与海藻酸钠比例、水样pH、萃取时间)、洗脱条件(洗脱溶剂比例、洗脱时间、洗脱体积)、离子强度(盐度)等方面对萃取效果进行优化,以获得最佳的萃取效果。优化结果显示,吸附剂在12 min内可以对目标物进行完全吸附,用总体积为4 mL的含1.5%甲酸的甲醇洗脱30 s,目标物可以充分解吸。在最优条件下,结合超高效液相色谱-串联质谱法(UHPLC-MS/MS),建立了基于金属有机骨架复合气凝胶测定水体中7种PCAs的新方法。该方法可以呈现良好的线性关系(r^(2)≥0.9986),检出限和定量限分别为0.30~1.52 ng/L和1.00~5.00 ng/L。在低(8 ng/L)、中(80 ng/L)、高(800 ng/L)3个水平下进行精密度试验,日内和日间精密度(以RSD计)分别为6.5%~17.1%和7.4%~19.4%。该方法应用于地表水、海水、垃圾渗滤液的检测中,检出量为0.6~19.3 ng/L;在8、80、800 ng/L 3个水平下进行加标回收试验,回收率为61.7%~120.3%。该方法具有良好的灵敏度、精密度和准确度,为环境水体中苯氧羧酸类物质的痕量检测提供了一种新的检测方法。