Effects of Hydrothermal Environment on the Deformation of the Thin Bamboo Bundle Veneer Laminated Composites

To overcome warping in thin bamboo bundle veneer laminated composites(TBLC),their hydrothermal deformation characteristics were systematically investigated in this study.It was found that TBLCs accelerated the release of internal stress in the thickness direction in a hydrothermal environment,which increased their warpage.TBLCs showed increased warpage in the width and diagonal directions upon increasing the temperature.The warpage of Type E increased by 155.88%and 66.67%in the width and diagonal directions,respectively,when the temperature increased from 25
C to 100
C.The symmetrical TBLC with cross-lay-up and odd layers displayed better hydrothermal stability.We revealed that the deformation of the TBLCs could be regulated under the synergistic effect of water and temperature.These results provide a scientific basis for improving the uniformity of bamboo bundle composite materials and for developing thin bamboo bundle fiber composite materials with designable structures and controllable performance.

Engineered Wood/Bamboo Laminated Composites for Outdoor Hydrophilic Platforms:Structural Design and Performance

Landscape designers increasingly prefer to use wood/bamboo-based composites for outdoor hydrophilic platforms owing to their natural surface texture,high performance,and sustainability to facilitate extensive interaction between people and water and enable the full range of ecological functions of water resources.In this study,four laminated composite(LC)structures were designed and manufactured using fluffed bamboo and wood veneers.Their surface textures,profile densities,water resistances,and mechanical properties were then evaluated.The type of fluffed veneer of the surface layer determined the texture of the LC surface.The specific structures of fluffed bamboo and wood veneer laminations were found to affect the LC profile density variability,water resistance,and mechanical properties owing to the differences in the strength and interfacial properties of bamboo and wood fibers.Finally,the water resistance and mechanical properties of all four LCs were found to be much higher than the highest level specified in GB/T 20241-2006 for“laminated veneer lumber”and GB/T 30364-2013 for“bamboo scrimber flooring”,indicating that they are promising materials for structures and flooring,particularly for outdoor hydrophilic platforms.

Control on Gradient Adhesive Loading of Porous Laminate:Effects on Multiple Performance of Composites with Bamboo Bundle and Sliver

Elementary units“bamboo bundle”and“bamboo sliver”were processed and cross-linked as“bamboo-bundle veneer(BBV)”and“bamboo-sliver veneer(BSV)”for preparation of laminated composites.The concept of“high-content-adhesive surface treatment”was raised to improve boards’performance,rather than increasing adhesive absorption of every layer’s porous unit.That is,some BBVs experienced an extra“dipping&drying”to absorb more resin(named“HBBV”).The effect of the amount of knitting threads was also discussed for influencing BBV’s quality.Results indicated that light transmittance of BBVs decreased as the amount of threads added from 3 to 8,while mechanical stiffness increased.Adding two skin layers of HBBVs symmetrically was helpful to enhance 24-hour underwater and 28-hour“boil-dry-boil”dimensional stability for boards with BSVs as core,while more than two pairs of HBBVs were needed to improve 28-hour“boil-dry-boil”dimensional stability of boards with BBVs as core.Two symmetrical surface layers of BBVs/HBBVs provided BSV-boards/BBV-boards with greater bending resistance,while such“surface treatment”would not raise shearing strength of BSV-boards upon 28-hour“boil-dry-boil”treatment.Besides,the data obtained from drop-hammer impact test indicated that more than two pair of surface BBVs or HBBVs were required for significant improvement in anti-impact property.

A Review of Basic Mechanical Behavior of Laminated Bamboo Lumber

Over the past decade,the physical and mechanical performances of laminated bamboo lumber(LBL)–a bamboo-based structural material,have been extensively studied using experimental,analytical,and numerical approaches.This paper presents a review of existing knowledge in the literature about the mechanical properties of LBL.The paper involved the review of the response of LBL to different types of loading such as tension,bending,compres-sion,and shear.Based on results of the literature reviewed,the strength of LBL parallel to grain was 90–124 MPa with MOE of 10700 MPa in tension,29.55–72.60 MPa,and MOE of 8396–11022 MPa in compression,63.87–128.4 MPa,and MOE of 8320–10912 MPa in bending,and 7.15–17.5 MPa in shear.The average strength of LBL was similar and in some cases exceeded the average values of bamboo-or wood-based materials,while the variability of its mechanical parameters was lower.The variability in strength values of LBL was affected by bamboo species,density and thickness of bamboo strips,growth portion,type of treatment,strips arrange-ments,and type of adhesive which in turn calls for classification of LBL by strength grades,degree of hardness,the capability of impregnation and penetration,as well as by areas of application in construction.The study pro-vided and discussed concluding observations,the current research gap,and future research directions on the mechanical properties of LBL.

竹集成材-SPF复合正交胶合木的研发及性能评估

运用相同工艺分别制备足尺垂直型竹集成材-SPF复合CLT(简称V-BWCLT)与足尺水平型竹集成材-SPF复合CLT(简称H-BWCLT)。依据国内外相关标准对两种BWCLT的胶层剪切强度、胶合耐久性、抗弯弹性模量(MOE)、抗弯强度(MOR)和层间剪切强度进行了测试,并用三维非接触式应变测量系统(DIC)对抗弯和层间抗剪试验过程中的受力变形情况进行记录。结果表明:在相同制备工艺条件下,两种BWCLT平均胶层剪切强度接近,浸渍剥离率均可达到相关标准要求。V-BWCLT的平均MOE与MOR分别为7941 MPa和56.7 MPa,而H-BWCLT的平均MOE与MOR分别为10144 MPa和54.0 MPa,H-BWCLT比V-BWCLT具有更高的弯曲刚度,但两者MOR较为接近。对比SPF-CLT,两种BWCLT的抗弯强重比均有显著提高,上述研究和分析为新型竹木复合CLT的实际工程应用提供了设计参考与理论依据。

LVL结构调控及应用研究进展

在我国木材资源紧缺、人工林材质较差、而竹材资源较为丰富的背景下,单板层积材(Laminated Veneer Lumber,LVL)作为一种生物质工程材料,具备高效利用现有资源的优势,并且以其出色的力学性能可实现标准化、系列化生产,展现出广阔的应用前景。本文结合我国人造板产业的发展现况,概述了LVL的起源和发展,着重从复合材料力学性能的角度分析了LVL的结构特点,对单板分等和LVL组坯特点进行了介绍。同时,综述了酚醛树脂浸渍和纤维材料复合两种LVL增强方式。最后,对比讨论了国内外LVL的评价标准,并针对我国木结构建筑产业的发展现状和LVL应用过程中存在的问题,提出了若干建议。

分层回填施工过程竹缠绕复合管涵力学性能研究

为解决竹缠绕复合管涵在分层回填的施工控制问题,并研究此过程中管涵的力学性能,文中通过现场试验,监测2m埋深竹缠绕复合管涵施工过程变形与与力学响应,建立了基于连续壳复合材料叠层的有限元分析模型。数据分析表明,土压力、管底沉降均随回填高度增加线性增大,浅埋阶段,受施工扰动影响,实测值偏大;回填完成后,管涵的计算与模拟竖向变形率分别为1.32%、1.57%,均满足规范要求。建议竹缠绕复合管涵管底沉降与管涵横截面变形可作为施工质量控制指标;所建立模型能较为保守地预测管土响应,可为后续研究提供参考。

胶合竹-混凝土组合梁研究进展

对胶合竹-混凝土组合梁(BCC梁)的发展和研究现状进行阐述,并对国内外的研究成果进行分析和总结。对比分析了木-混凝土组合梁(TCC梁)和BCC梁剪力连接件的抗剪性能,并对足尺梁的破坏模式、组合效应进行分析和总结。最后,根据EN:1995-1-1:2004中已有的有效刚度公式进行理论推导。综述发现,国外TCC梁的试验研究已开展较多,国内BCC梁的研究正在兴起,但针对不同种类剪力连接件的BCC梁的破坏模式和受力机理仍缺乏系统的总结。此外,BCC梁的研究迫切需要一套能满足设计要求的计算理论和设计方法。

竹-橡胶木复合正交胶合木的制备和性能

以锯材为基本单元的正交胶合木是具有广泛应用前景的重型木结构建筑材料。为减少对国外树种的进口和依赖,首次采用竹篾层积材与橡胶木2种本土层板原料,以相同制备工艺(胶黏剂为单组分聚氨酯,施胶量为180 g/m^(2),冷压时间1 h,压力为1.0 MPa),在大幅面压机上压制尺寸为2400 mm×1200 mm×96 mm的三层竹木复合正交胶合木(cross-laminated timber,CLT)以及另外3种不同复合形式的CLT(纯木CLT、木竹复合CLT、纯竹CLT),通过对竹木复合CLT强轴方向的抗弯弹性模量、抗弯强度、胶层剪切强度、层间剪切强度和浸渍剥离率等性能的评估和不同复合形式CLT弯曲性能差异的分析,研究国内树种与竹材制备足尺竹木复合CLT的可行性。结果表明:采用单组分聚氨酯制备的竹木复合CLT,其干态和真空加压状态下的强度、木破率以及浸渍剥离率均符合ANSI APA PRG 320-2019“Standard for performance-rated cross-laminated timber”中使用环境1的要求;抗弯性能和剪切性能测试值均能达到以上标准和LY/T 3039—2018《正交胶合木》标准中E2等级性能的要求。上述试验研究和分析为竹木复合CLT在建筑工程中的应用提供了设计参考及理论依据。

表板厚度与组坯方式对展平竹-杨木复合板性能的影响

为充分发挥杨木与展平竹的优势,以杨木为芯板、展平竹为表板制作展平竹-杨木复合板,分析表板厚度(2、4、6、8 mm)及组坯方式(顺纹组坯、横纹组坯)对复合板弹性模量、抗弯强度、冲击韧性及胶合强度的影响。结果表明:在表板厚度方面,随表板厚度增加,复合板抗弯弹性模量先减小后增加,表板为8 mm的复合板弹性模量最大,为12.10 GPa;抗弯强度呈下降趋势,表板为2 mm的复合板抗弯强度最大,为198.4 MPa;冲击韧性呈上升趋势,表板为8 mm的复合板冲击韧性最大,为50.19 kJ/m^(2);胶合强度先增加后减小,表板为4 mm的复合板胶合强度最大,为5.41 MPa。在组坯方式方面,横纹组坯复合板的弹性模量、抗弯强度、冲击韧性优于顺纹;与顺纹组坯相比,横纹组坯复合板的抗弯弹性模量高9.82%、抗弯强度高18.67%、冲击韧性高2.20%;胶合强度以顺纹组坯复合板为高,达5.41 MPa,横纹组坯的为3.73 MPa。

表板热处理温度对展平竹—杨木复合板物理力学性能的影响

【目的】充分发挥杨木与竹展平板各自的性能优势。【方法】以不同温度(120℃、140℃、160℃,0 MPa处理2 h)热处理的竹展平板为表板,杨木单板为芯板顺纹组坯制作展平竹—杨木复合板,通过测试其含水率、色差、光泽度、胶合强度、浸渍剥离率、抗弯强度、抗弯弹性模量等性能,分析表板热处理对复合板材物理力学性能的影响。【结果】物理性质方面,表板热处理使得复合板含水率大幅度降低;光泽度逐渐减小,色觉稳定性增大;总色差皆大于1.5,但材色变化不明显;胶合性质方面,表板热处理使得复合板胶合强度下降,140℃处理时达最低值;浸渍剥离试验表明,表板热处理使得复合板胶合耐久性先增强后减弱;力学性质方面,随表板热处理温度的升高,弹性模量、抗弯强度均有一定提高,140℃处理时达最大值。【结论】表板热处理丰富了展平竹—杨木复合板的视觉效果,改善了复合板的抗弯强度、弹性模量,但对复合板的胶合性能具有一定的不利影响,实际使用中应根据具体需求进行选择。

竹材增强杨木单板层积材冲击性能的研究

研究了在杨木单板层积材中加入竹材作为增强材料,以提高杨木单板层积材冲击性能。结果表明:将竹材加入杨木单板层积材,可以明显地改善杨木单板层积材的冲击韧性。当竹篾分别加入杨木单板层积材的上下次表层和中间部位时,其冲击韧性分别增强了30.4%和27.3%;总冲击能分别提高了31.7%和28.1%。裂纹形成能仅增长7.2%和12.8%;裂纹扩展能增长40.9%和43.4%;韧性指数值提高了27.2%和31.5%。

先进生物质复合材料在风电叶片中的应用

竹材是生长速度快、性能好的生物质材料之一。由于竹材外侧性能远高于内侧,采用分级加工方法可制备由外侧到内侧的A、B、C、D级竹层积材。通过与其他风电叶片材料比较,A级竹篾层积材的性能超过了目前风电叶片使用的木层积材,与玻璃纤维增强塑料的性能接近。用这种先进生物质复合材料制作的新一代风电叶片,具有可再生性、加工消耗能源少、无废弃物、成本低、废旧产品易于处理等一系列优点。

不同树种木材复合交错层压胶合木的力学性能

采用花旗松、辐射松和杨木,即将杨木置于芯层,花旗松或者辐射松置于表层,压制单一树种和混合树种交错层压胶合木(Cross-laminated timber,CLT),对材料进行顺纹抗弯、顺纹抗剪和横纹抗剪性能测试。试验表明,相比抗弯弹性模量最低的纯杨木CLT,花旗松与杨木混合CLT的性能提高35%;包含杨木和不包含杨木的不同树种CLT顺纹抗弯强度及抗剪强度差别不大。试件破坏形式与CLT材料和结构形式有很大联系,主要包含指接处破坏、胶层分层和垂直层滚动剪切破坏等。

竹木复合层积材结构及其性能

运用复合材料力学层合板理论对竹木复合层积材进行结构设计与试验。结果表明:以高密度竹帘胶合板为强化面层,马尾松板材为芯层,采用特殊的二次热压生产工艺,研制出的竹木复合层积材物理、力学性能良好,能够满足铁路平车地板对强度、耐候性、耐磨性、握钉力等性能的特殊要求。

原竹对剖联丝展开片材加工与竹木复合层积材制造技术

原竹对剖联丝展开片材制造方法是:先将原竹一分为二破开,再经交错劈破形成竹联丝片材,基本上保留了竹、竹黄,只需要去掉少量两侧三角边。原材料利用率提高到85%。简化了板材加工工艺,提高了工作效率,加工成本降低15%～20%。以原竹对剖联丝展开片材与杨木单板复合、涂胶、热压,制成竹木复合板材。产品的表面为竹青面,从而大大提高了产品的表面硬度。产品各项性能指标均超过了国家标准要求,产业化和市场需求前景广阔。

胶合竹-混凝土组合梁销栓连接性能试验研究

采用植筋螺杆作为连接件,对6组胶合竹-混凝土组合试件进行剪切滑移试验,测得了荷载-滑移曲线、抗剪承载力和抗滑移刚度等基本力学指标,并对不同组合方式进行了分析和比较.研究结果表明:组合试件的主要破坏模式为GluBam在螺杆局部挤胀作用下的纵向开裂和螺杆在胶合竹梁内部产生显著的弯折变形;组合试件的抗剪切性能随着螺杆直径的增大而增强,但提高效应呈递减趋势,选用直径为18mm的螺杆作为连接件较为合理;提高螺杆强度等级对改善组合试件的抗剪切刚度和组合梁的组合效应没有实质性作用;在组合界面设置防水层,对胶合竹梁含水率的影响是暂时的,可以取消.

不同因素对竹／木复合强化单板层积材MOE、MOR的影响

以杨木单板和竹帘为原料,采用低分子量水溶性酚醛树脂浸渍处理,通过干燥、组坯、热压等工艺制备竹木复合强化单板层积材。探讨了组坯方式、压缩率、热压温度、热压时间4个因素对竹木复合强化单板层积材弹性模量(MOE)和静曲强度(MOR)的影响。结果表明:表层为一层竹帘的竹木复合强化单板层积材的MOE和MOR较大,分别是13．43GPa、148．13MPa,与表层为杨木单板次表层为竹帘组坯方式相比分别增加了33．63％、56．16％。确定了竹木复合强化单板层积材较合理的制造工艺参数。

环境温湿度对竹材增强LVL力学性能的影响

在不同温湿度条件下,对竹材增强单板层积材(LVL)进行处理,分析了经过处理后竹材增强LVL力学性能的变化。结果表明:经过高温高湿处理后,竹材增强LVL的力学性能均出现了明显的衰减。其中,弹性模量(MOE)平均衰减30.7%,静曲强度(MOR)平均衰减38.3%,冲击韧性平均衰减11.7%;经过低温处理后,竹材增强LVL的弹性模量和静曲强度都有微弱增长的趋势,弹性模量平均增长率为2.5%,静曲强度平均增长率为5.4%,冲击韧性平均衰减率为37.9%;在高低温交变处理过程中,竹材增强LVL的弹性模量和静曲强度处于上下波动的状态,弹性模量衰减率或增长率在5%以内,静曲强度衰减率或增长率在10%以内,冲击韧性呈衰减趋势,平均衰减率为18.7%。

厚单板制备木质复合板材的工艺、关键设备和性能

针对木材单板化利用受限于单板厚度的难题,提出采用4~10 mm厚度单板制备木质复合板材的技术方案,介绍厚单板旋切、展平和干燥等关键工序的技术和设备特点,以及采用厚单板制备胶合板、单板层积材和竹木复合板材等3种木质复合板材的制备工艺和主要性能,为厚单板的产业化利用提供技术支撑。