Effect of polypropylene fiber and coarse aggregate on the ductility and fluidity of cemented tailings backfill

Adding polypropylene(PP)fibers and coarse aggregates has become a popular way to enhance the strength and stability of the cemented tailings backfilling(CTB)body.It is essential to explore the influence of tailings-aggregate ratio and fiber content on the mechanical properties of CTB samples.The comprehensive tests of the unconfined compressive strength(UCS),slump and microstructure were designed,and the regression models were established to characterize the effect of the strength,ductility and fluidity.The results indicate that the tailings-aggregate ratio of 5:5 and PP fiber content of 0.5 kg/m^(3) are the optimum point considering the UCS,cracking strain,peak strain and post-peak ductility.The tailings-aggregate ratio is consistent with the unary quadratic to the UCS and a linear model with a negative slope to the slump.Microstructural analysis indicates that PP fiber tends to bridge the cracks and rod-mill sand to serve as the skeleton of the paste matrix,which can enhance the compactness and improve the ductility of the CTB.The results presented here are of great significance to the understanding and application of coarse aggregates and fibers to improve the mechanical properties of CTB.

Entrance and Exit Defects During Coarse Pitch Orbital Drilling of Carbon Fiber Reinforced Plastic Plates

Formation of entrance and exit defects in coarse pitch orbital drilling(CPOD)of carbon fiber reinforced plastic(CFRP)plates was investigated.Deep observation on entrance and exit morphology shows tear and burr are typical defects.Meanwhile,tear is more obvious than burr,and more entrance tears emerge than exit tears.As one of the major causes of entrance and exit defects in CPOD,cutting forces were substaintially studied by contrast experiments.Then,the effect of cutting parameters on entrance and exit tear was qualitatively analyzed through a single factor test.Experiment results indicate that the variation of rotation speed has little influence on entrance and exit tear.Increasing tangential feed per tooth can enlarge entrance tear,but bring little effect on exit tear.By increasing axial feed pitch,the hole entrance and exit show severe tear.When revolution radius grows bigger and bigger,entrance and exit tear firstly decreases,and then increases.Finally,the models of tear and delamination during CPOD of CFRP were established,the formation mechanisms of entrance and exit defects were revealed,and the control strategies were accordingly put forward.

Punching shear behavior of steel fiber reinforced recycled coarse aggregate concrete two-way slab without shear reinforcement

In this paper,the punching shear performance of 8 steel fiber reinforced recycled coarse aggregate concrete(SFRCAC)two-way slabs with a size of 1800 mm×1800 mm×150 mm was studied under local concentric load.The effects of RCA replacement ratio(rg)and SF volume fraction(Vf)on the punching shear performance of SFRCAC two-way slabs were investigated.Digital Image Correlation(DIC)measurement and Acoustic Emission(AE)technique were introduced to collect pictures and relevant data during the punching shear test.The test results show that the SFRCAC two-way slab mainly exhibits punching shear failure and flexure failure under local concentric load.The punching shear failure space area of SFRCAC two-way slab has no obvious change with increasing rg,however,show a gradual increase trend with increasing Vf.Both of the punching shear ultimate bearing capacity(Pu)and its deflection of SFRCAC two-way slab decrease with increasing rg and increase with increasing Vf,respectively.Finally,through the regression analysis of the results from this study and the data collected from related literature,the influence of rg and Vf on the Pu of two-way slabs were obtained,and the equations in GB 50010-2010,ACI 318-19,and Eurocode 2 Codes were amended,respectively.Furthermore,the amended equations were all applicable to predicted the ultimate bearing capacity of the ordinary concrete two-way slab,RCAC two-way slab,SFRC two-way slab,and SFRCAC two-way slab.

基于纤维-骨料细观分布的自密实钢纤维混凝土单调和循环压缩性能研究

自密实钢纤维混凝土(SFRSCC)压缩性能表现和内部组分含量及分散状态均具有显著关联。为探究这种关联特性,定制不同组分配比的SFRSCC拌合物来浇筑制备棱柱体试块,并分别开展单调及循环压缩实验探索其压缩性能特性研究;随后截取每组试块的数个特征截面,采用粗骨料面积占比来描述粗骨料含量,将钢纤维含量及分散情况量化为Voronoi增韧面积统计值,并结合实测数据建立压缩力学特性和内部组分含量及分布特性之间的关联。参考上述关联特性,建立SFRSCC单调和循环压缩弹塑性损伤本构性能曲线方程。研究结果表明:粗骨料含量的增长提高了基体弹性模量和峰值强度,但骨料胶结难以抑制宏观裂缝的非稳定扩展;纤维数量的增加可减小钢纤维的增韧区域面积,从而能够延缓峰后塑性变形的累积,控制宏观裂缝生成,这种增韧效应和Voronoi增韧面积呈负相关,与增韧效率系数呈正相关;在自密实工艺下,钢纤维数量增加会抑制粗骨料含量的增长,需平衡Voronoi面积和粗骨料面积占比以满足增韧与增强需求。建立的SFRSCC单调和循环压缩弹塑性损伤本构性能曲线方程可实现不同组分分布下SFRSCC结构局部压缩性能的可靠分析。

复掺纤维对再生粗集料沥青混合料性能影响的研究

为提高建筑垃圾利用率,改善再生粗集料沥青混合料(RA-AM)的路用性能,研究复掺纤维在沥青混合料中的质量掺量为0.3%,选定木质纤维与玄武岩纤维的质量比分别为0∶1、1∶3、1∶1、3∶1和1∶0,以确定RA-AM中木质纤维(XF)和玄武岩纤维(BF)的最优复掺比例。结果表明:随着木质纤维占比的提高,MS、T、动稳定度、MS 1、MS 0先增加后降低,FL先降低后增加,复掺比例为25%即m(木质纤维):m(玄武岩纤维)=1∶3时MS、T、动稳定度、MS 1、MS 0最大,FL最小,相比纯沥青,此时混合料的MS增加75.55%,FL降低29.38%,T增加148.46%,动稳定度增加57.62%,MS 1增加120.59%,MS 0增加25.66%。因此复掺BF和XF比单掺效果更好,且m(XF)∶m(BF)=1∶3时效果最好。

含粗骨料超高性能混凝土的单轴受拉力学性能

考虑粗骨料掺量、钢纤维掺量及长径比等因素,研究了含粗骨料超高性能混凝土(UHPC-CA)的单轴受拉力学性能,揭示了纤维增强的机理和粗骨料的作用机制.结果表明:随着粗骨料掺量的增加,UHPC-CA的单轴抗拉强度与变形性能均下降;钢纤维掺量增加、长径比增大对UHPC-CA的受拉力学性能有较大的提升作用;钢纤维与基体间具有良好的握裹力,在基体内出现裂缝后,主要依靠握裹作用承受拉应力;粗骨料的掺入削弱了钢纤维空间分布的均匀性,同时引入了薄弱的粗骨料-基体界面过渡区,对UHPC-CA的受拉性能产生了不利的影响.

粗骨料及混杂纤维对UHPC力学性能的影响

为评议粗骨料超高性能混凝土(CA–UHPC)的基体配合比设计方法及探究混杂纤维对其力学性能的影响,基于修正的安德森(MAA)模型提出CA–UHPC基体配合比的两种设计思路,对不同粗骨料体积掺量(10%,12%,14%,17%)及混杂纤维形式(平直钢纤维、端钩钢纤维、共聚甲醛(POM)纤维)的CA–UHPC开展轴拉试验、抗压强度及工作性能测试及微观结构分析.结果表明:采用MAA模型计算CA–UHPC的基体配合比,不论是否将粗骨料引入计算体系,均可实现CA–UHPC的紧密堆积状态,两种思路设计的CA–UHPC中粗骨料–UHPC基体界面及纤维–UHPC基体界面的粘结强度均较高;制备的混杂纤维CA–UHPC可实现工作性能与轴拉韧性的协同提升,其中平直钢纤维与端钩钢纤维混杂的CA–UHPC具备更优异的轴拉韧性,平直钢纤维与POM纤维混杂的CA–UHPC具备更优异的工作性能;拔出的POM纤维表面存在较多的细长絮状物,说明POM纤维对CA–UHPC轴拉韧性提升的机理为优异的化学粘结作用.

粗骨料纤维充填体的力学特性与能量损伤演变规律

为提升充填体的抗拉性能、抗裂性能和韧性,通过抗压、巴西劈裂和落锤冲击试验研究了聚丙烯纤维对充填体强度特征、变形特征、抗冲击性能和能量演变的影响。结果表明:随着纤维掺量增加,充填体强度先增大后减小,弹性模量逐渐降低;掺入纤维后,充填体总耗能增加,达到峰值后释放动能减小,摩擦内能增加,可促进弹性应变能转变为耗散应变能;随着纤维掺量增加,充填体冲击耗能、延性比和韧性系数先增大后减小,终裂形态由“开裂即碎”演变为“裂而不碎”;掺入0.10%纤维的充填体抗拉强度、韧性和抗冲击等性能最优。强化机制主要是充填体内纤维“筋网结构”延缓裂纹产生、抑制裂纹扩展和提升能量吸收上限。研究成果有助于提升采场充填体顶板的稳定性,保障矿山生产作业安全。

不同纤维掺量再生混凝土骨料轻质混凝土性能研究

为了研究聚丙烯(PP)纤维增强再生混凝土骨料轻质混凝土的性能,以普通硅酸盐水泥、再生废弃混凝土粗骨料、聚丙烯纤维、泡沫为主要材料,选取PP纤维掺量为变量,对试样进行室内试验研究。结果表明:随PP纤维掺量增加,浆体流动度呈下降趋势;当采用再生粗骨料级配(即粒径为9.5~16 mm、16~19 mm、19~26.5 mm、26.5~31.5 mm、31.5~37.5 mm的5类骨料的质量比)为2∶4∶8∶3∶3和30%体积率时,建议浆体流动度大于210 mm;试件抗压强度和劈裂抗拉强度随PP纤维掺量的增加均呈先增大后减小趋势,说明PP纤维对再生混凝土骨料轻质混凝土性能提升效果有限;PP纤维的掺入会使再生混凝土骨料轻质混凝土材料早期抗压强度和劈裂抗拉强度形成速度降低;当纤维掺量由0增大为0.2%时,增加了孔隙率,降低了平均孔径。

再生混凝土电化学除氯效率的影响因素及敏感性

电化学除氯技术应用于受氯盐侵蚀的混凝土结构,以提高混凝土的耐久性。再生混凝土电化学除氯效率受多种因素的影响,研究再生混凝土的材料和外加剂、电化学参数对提高除氯效率具有重要意义。试验通过研究再生粗骨料粒径和取代率、聚丙烯纤维、减水剂、电流密度和除氯时间对再生混凝土电化学除氯效率的影响,分析除氯后残余氯离子分布,并对电化学除氯效率进行敏感性分析。结果表明:再生粗骨料粒径增大,除氯效率先增大后减小;再生粗骨料取代率、聚丙烯纤维掺比、电流密度和除氯时间增加,除氯效率增大;减水剂掺量增大,除氯效率减小。极差法和方差法的敏感性分析结果相同,且敏感性由大到小依次为除氯时间、减水剂、电流密度、再生粗骨料粒径、再生粗骨料取代率、聚丙烯纤维。

粗骨料UHPC单轴拉伸性能及损伤本构模型

通过单轴拉伸试验,研究粗骨料用量和钢纤维的掺量、类型及混杂配比对粗骨料超高性能混凝土(CA-UHPC)受拉性能的影响,揭示了CA-UHPC破坏机理以及粗骨料与钢纤维的相互作用机制.结果表明:粗骨料引起的薄弱界面和空间阻隔作用削弱了钢纤维的增韧作用,CA-UHPC拉伸性能随粗骨料用量增大而降低,建议其用量不超过450 kg/m^(3);增大钢纤维掺量能改善CA-UHPC拉伸性能,且平直钢纤维的增韧作用更稳定;1.0%平直和1.0%端勾钢纤维混杂时,其与粗骨料匹配良好,钢纤维有效利用率达到25.4%,能够充分发挥混杂纤维的协同增韧作用.最后建立了考虑粗骨料和钢纤维影响的CA-UHPC受拉损伤本构模型.

高温后纤维增强全再生粗骨料混凝土力学性能试验研究

为研究高温后纤维增强全再生粗骨料混凝土力学性能,以历经最高温度、混杂纤维类型、纤维掺量为变化参数,设计并完成了44个试件的轴压试验,观察了高温后试件的表观变化及受力破坏形态,获取了荷载-位移曲线,分析了各变化参数对试件破坏形态、质量烧失率、峰值荷载和峰值变形的影响规律。结果表明:随历经最高温度升高,纤维全再生粗骨料混凝土表观由青灰色变淡红色,最后呈淡褐色,其质量烧失率近似呈线性增长;随温度的升高,试件破坏开裂时间越早,表观损伤越严重,而随钢纤维、玄武岩纤维掺量增加,试件裂缝发展减缓,整体性更好;试验范围内,掺钢-玄武岩纤维试件的峰值荷载随钢纤维掺量增加而减小,随玄武岩纤维掺量增加而增大,其峰值变形随两类纤维掺量的增加均表现为先增后减;对掺钢-聚丙烯纤维试件,随钢纤维掺量增加,峰值荷载先减后增,峰值变形增大,随聚丙烯纤维掺量增加,峰值荷载减小,峰值变形先减后增。

外粘碳纤维布加固混凝土的粘接性能研究

为了提升外粘碳纤维布加固混凝土的粘接性能,对比分析了未掺加钢纤维和掺加不同含量钢纤维的外粘碳纤维布加固混凝土的粘接性能。结果表明,掺加钢纤维可以提升混凝土试件的抗压强度、劈拉强度、极限荷载、峰值扰度和最大应变,从而对混凝土起到加固作用;掺加钢纤维试件的极限荷载要高于未掺加钢纤维的试件,且钢纤维掺加量越大则极限荷载越大,界面滑移也越大;都使用再生骨料混凝土的情况下,掺加钢纤维试件的有效粘接长度大于未掺加钢纤维的试件,且当钢纤维掺加量较大时试件有效粘接长度要高于未使用再生粗骨料的试件。

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。

含粗骨料超高性能混凝土静态稳定性研究

为改善含粗骨料超高性能混凝土(CA-UHPC)整体静态稳定性,采用图像技术分别研究了拌合物(未加纤维)流变参数、粗骨料掺量和粗骨料级配对不含纤维和含纤维CA-UHPC静态稳定性的影响规律。结果表明:粗骨料整体均匀性随粗骨料平均初始净距的减小而升高;当拌合物的屈服应力和塑性粘度较小时,纤维分布的均匀性会因纤维沉降而降低;纤维的加入降低了粗骨料的整体均匀性,同时粗骨料也会影响纤维的整体均匀性;对CA-UHPC体系而言,粗骨料平均初始净距的减小可以增加粗骨料分布稳定性,但过小的粗骨料平均初始净距会影响纤维的分布。因此,在粗骨料掺量一定时,可以通过适当调整粗骨料级配或砂率,在不影响粗骨料分布稳定性的前提下,提高纤维分布系数。

Bond-Slip Behavior of Steel Bar and Recycled Steel Fibre-Reinforced Concrete

Recycled steel fiber reinforced concrete is an innovative construction material that offers exceptional mechanical properties and durability.It is considered a sustainable material due to its low carbon footprint and environmental friendly characteristics.This study examines the key influencing factors that affect the behavior of this material,such as the steel fiber volume ratio,recycled aggregate replacement rate,concrete strength grade,anchorage length,and stirrup constraint.The study investigates the bond failure morphology,bond-slip,and bond strength constitutive relationship of steel fiber recycled concrete.The results show that the addition of steel fibers at 0.5%,1.0%,and 1.5%volume ratios can improve the ultimate bond strength of pull-out specimens by 9.05%,6.94%,and 5.52%,respectively.The replacement rate of recycled aggregate has minimal effect on the typical bond strength of pull-out specimens.However,the ultimate bond strengths of pull-out specimens with concrete strength grades C45 and C60 have improved compared to those with C30 grade.The specimens with longer anchorage lengths exhibit lower ultimate bond strength,with a reduction of 33.19%and 46.37%for anchorage lengths of 5D and 7D,respectively,compared to those without stirrups.Stirrup restraint of 1φ8 and 2φ8 improves the ultimate bond strength by 5.29%and 6.90%,respectively.Steel fibers have a significant effect on the behavior of concrete after it cracks,especially during the stable expansion stage,crack instability expansion stage,and failure stage.

外源氮添加对扎鲁特旗山地草原主要植物饲用品质的影响

为促进草地合理利用,2021年和2022年通过连续对扎鲁特旗山地草原进行氮添加,调查样地群落及主要植物粗蛋白、粗纤维、粗脂肪、粗灰分等指标,运用主成分分析方法进行量化综合评价,探讨氮添加对山地草原群落及主要植物饲用品质的影响规律。结果表明,草地植物营养价值大小排序为止血马唐(Digitaria ischaemum)>冰草(Agropyron cristatum)>寸草苔(Carex duriuscula)>达乌里胡枝子(Lespedeza daurica)>糙隐子草(Cleistogenes squarrosa)>扁蓿豆(Medicago ruthenica)。短期的氮添加可以显著增加山地草原植物粗蛋白、粗脂肪和中性洗涤纤维含量,对酸性洗涤纤维、粗灰分和干物质产量影响不显著,随着氮素比例的增加,群落内的粗蛋白含量、粗脂肪含量、中性洗涤纤维含量和干物质产量呈先增加后降低趋势,而酸性洗涤纤维和灰分呈降低趋势。施加氮肥可以显著提高禾本科植物的营养价值,对豆科牧草的影响不显著,能够显著提高草地营养价值的施氮量为O_(4)I_(0)(有机态氮4 g·m^(-2)·a^(-1))。

含粗骨料UHPC的强度尺寸效应与性能研究

研究了胶凝材料组成比例、钢纤维类型(平直型、端钩型)对含粗骨料超高性能混凝土(UHPC)强度尺寸效应、工作性和收缩性能的影响,分析了减缩剂掺量(0~2.0%)对含粗骨料UHPC收缩性能、力学性能、抗氯离子渗透性能和孔结构的影响。结果表明:适当增加粉煤灰掺量有利于改善含粗骨料UHPC的工作性,降低收缩;掺入钢纤维降低了含粗骨料UHPC的工作性,但抑制了收缩,且端钩型钢纤维抑制效果更显著;掺入1%钢纤维能够有效降低含粗骨料UHPC的强度尺寸效应,且平直型钢纤维的降低效果更好;掺入减缩剂明显降低了含粗骨料UHPC的收缩,但会使抗压强度降低,总孔隙率增大,抗氯离子渗透性能变差。

DIO环吹粗旦多孔纤维的开发

涤纶粗旦多孔纤维目前在国内一般都采用侧吹风或环吹风单通道组件生产,不但生产成本高,产品品质也很难达到客户的要求。因此,通过DIO环吹粗旦多孔纤维的开发来提高生产质量,可以更好地满足市场需求,提高企业的生产效益。基于此,文章就DIO环吹粗旦多孔纤维的开发进行了研究,以期能够为该产品的生产提供科学技术参考。

纤维地聚物复合改良粗粒填料动力变形特性试验研究

纤维地聚物复合改良可提升粗粒填料强度、刚度等性能,减小受长期动载作用引发的累积塑性变形。通过抗压强度试验探讨地聚物理想组分设计及其与纤维在土中的最佳配比,然后开展纤维地聚物复合改良粗粒填料抗压、循环加卸载试验,分析块石含量、应力水平对其累积变形特性和破坏模式的影响。结果表明:地聚物中偏高岭土、硅酸钠和生石灰最佳质量比为3.6∶1∶0.8,三者在土中最优掺量为15%,纤维最佳掺量和长度为0.4%和12mm;纤维地聚物复合改良粗粒填料抗压强度随块石含量呈先增后减再增变化,块石含量30%时其力学性能最好;纤维地聚物复合改良粗粒填料动力累积应变速率随循环加卸载次数增加呈先快后慢再快发展,随块石含量、荷载水平提高,裂隙数量和扩展速率增加明显,破坏模式由剪切滑移向竖向劈裂转变。研究成果可为纤维地聚物复合改良粗粒填料动力特性认知和工程应用提供参考。