木塑与钢材复合温室骨架设计及力学性能试验

木塑复合材料是近几年发展较快的一种新型材料,具有易加工、密度高、硬度强的特点。为探究木塑在温室建筑上的应用,设计了一种适合温室使用的木塑与钢材复合骨架,并进行力学性能试验。该试验以木塑和钢材为试材,采用拉伸、压缩、人工气候老化及复合骨架应用于温室的方法,研究了其抗拉、抗压强度及其在温室中应用情况,以期能够开发一种在性能和价格上与钢骨架结构材料相媲美的新材料。结果表明:在低温、室温和高温条件下,木塑的抗拉强度分别为28.391、24.954、15.000 MPa,木塑的抗压强度分别为63.633、42.438、32.547 MPa,木塑的抗拉强度和抗压强度均与环境温度呈负相关关系。木塑在经过250 h的人工气候老化后的抗弯强度为37.040 MPa,比未进行老化处理下降了22.083%。将木塑与钢材结合制作成不同形式的复合骨架,与普通木塑骨架对比,在室温下测试发现复合骨架比普通木塑骨架抗弯性能显著提高,其延展性提高约3倍,其中钢材添加在下缘的复合骨架的抗弯性能显著较钢材在上缘的复合骨架优越;带卡簧卡槽复合骨架的最大抗弯屈服力为19.112 kN,较钢材在下缘的复合骨架提高88.74%,达到了温室骨架的承载力要求。通过供试带卡簧卡槽复合骨架温室的荷载试验得出,跨度8.0 m、顶高3.3 m的拱形屋面温室,其骨架间距为1.2 m时,供试温室承受荷载为0.436 kN·m^-2;当骨架间距为1.0 m时,其承受荷载为0.527 kN·m^-2。与传统钢骨架温室对比,复合骨架温室的建筑成本减少了10.4元·m^-2。该复合骨架可以同时发挥木塑的环保、价廉、可塑性优势和钢材的优良力学性能,为温室建筑的轻简化、装配化提供了有益参考。     

木材横纹压缩大变形应力－应变关系的定量表征

在１００—１３００ｋｇ／ｍ３的密度变异范围选取１７种阔叶树试树，采用典型的６种木材压缩加工条件（气干·２０℃：饱水·２０℃：饱水·１００℃３种条件与约束条件相组合），进行横纹大变形压缩试验和数字化数据采集，经数据分析处理，建立了定量描述木材横纹压缩大变形全领域应力－应交关系的数学表达式。该式的适用性对本试验范围内的各树种、压缩工艺条件均为有效，计算值与实测值十分吻合。     

梁弯曲振动边界元法仿真研究初探

简要分析了有限元法和边界元法在梁类零件振动仿真分析中的优点和缺点．梁是常用的机械结构件,在工程机械中的应用非常广泛．应用边界元法对矩形梁弯曲振动进行了仿真分析,当梁的弹性常数不变而横截面的高宽比改变时．其固有振动频率会相应地改变,为通过改变结构参数来改善梁结构的动力学性能进行理论探索．     

木塑构件强度特性的研究

在包装、家具框架中L型构件是一种比较常见的结构形式.本文通过分析跨距对木塑L型构件结构强度和连接结构强度的影响,得出以下结论:跨距对木塑L型构件结构强度的影响非常显著,跨距越短,结构强度越大;跨距对连接结构强度影响也很大,跨距在190mm左右时,连接性能最好.     

肇松松花江特大桥高程监控中温度影响的探讨

在悬臂浇筑法施工中，如何控制主梁的标高及其变化，是施工监控所要解决的首要问题之一。而影响悬臂浇筑法施工的因素众多，有梁体自重、张拉力、混凝土的收缩、徐变、活载和温度变化引起标高变化。在肇松松花江特大桥施工控制实践中，温度变化引起悬臂箱梁标高不断发生变化，主要是竖向温度场的变化引起各悬浇块标高的变化，即由日照温度变化引起的变形。此项变形值在施工高程控制中以实测的温度变形速度计入。     

地下防水工程渗漏水的修堵

作者结合实践,分析了地下工程渗漏水的原因往往是由于设计不合理及施工不规范而造成的,并提出了相应的防治措施。     

Growth and water potential of j-rooted loblolly and eastern white pine seedlings over three growing seasons

The effects of j-rooting on water stress and growth of loblolly (Pious taeda L.) and eastern white pine (Pious strobus L.) were examined over three growing seasons in the field. Seedlings were planted in an area with severe herbaceous competition with either their roots planted straight or bent into a j shape. All seedlings were planted with their root collars placed at the soil surface. During the first year j-rooted seedlings consistently had lower water potentials but never statistically significant. Since both treatments were planted with the root collar at the soil surface, this trend was likely due to an initial shallower root system in j-rooted seedlings. In year three no differences in water potential were significant and no trends were evident. Growth did not differ significantly by treatment at any time but, by year three, j-rooted plants were consistently larger for both species.     

Compressive deformation of wood impregnated with low molecular weight phenol formaldehyde (PF) resin II: effects of processing parameters

To obtain high-strength phenol formaldehyde (PF) resin-impregnated compressed wood at low pressing pressure, the effects of resin content, preheating temperature, pressing temperature, and pressing speed on the compressive deformation of oven-dried low molecular weight PF resin-impregnated wood was investigated. With an increase of PF resin content, the Youngs modulus of the cell wall perpendicular to the fiber direction decreases, and collapse-initiating pressure decreases linearly with the Youngs modulus. This indicates that the occurrence of cell wall collapse is strain-dependent. By increasing preheating temperatures, the collapse-initiating pressure increases due to the increment of the Youngs modulus of the cell wall. An increase in pressing temperature results in the thermal softening of the cell wall and causes collapse at a lower pressure. The wood is compressed effectively despite accelerated resin curing. The pressing speed significantly affects the viscoelastic deformation of the cell wall and the wood is well deformed with decreasing pressing speed, although the differences in density and mechanical properties are relatively small after a pressure-holding period of 30min. In all the parameters examined in this study, the Youngs modulus and bending strength increase with increasing density.     

Current Research and Development on Deformation and Fixation of Bended Wood and Wood-based Composites

There are many advantages of bended wood,such as good-looking shape,simple process and low cost.The product,however,is easy to get recovery,which is urgent to be dealt with.This paper concludes the features of deformation and recovery of bended wood and wood-based composites and summarizes four treating methods to keep dimensional stability.Compared to bended solid wood,some elementary perspectives on the research of bended wood-based composites are presented.The purpose of this paper is to suggest:1)to investigate the optimum heating time and temperature that bended wood and wood-based composites need from the formation of deformation to the recovery and to the permanent fixation,according to its changes of dimensional stability such as curvature radius;2)to measure the composites comprised of wood and adhesives on the changes of stress relaxation,dynamic viscoelasticity and crystal1ization field;3)to quantitatively analyze changes of the major components in wood cell wall polymers as well as the composites under heat/steam treatment and untreated conditions.It will be helpful for subsequent research to clarify on the mechanisms of permanent fixation of bended wood and also contribute to that of wood-based composites.     

三层实木复合地板弯曲变形原因及控制措施

阐述了三层实木复合地板的结构特点,对其产生弯曲变形的原因进行分析,并结合生产实际提出了三层实木复合地板的质量控制措施。