天然林五角槭木材材质径向变异规律初探

以天然林五角槭的木材解剖性质为研究对象,分析其株内木材材质径向变异规律,对幼龄材与成熟材进行初步界定。结果表明:细胞壁厚、壁腔比、胞壁率和径、弦向直径幼龄期波动较大,成熟期波动减弱;木纤维长度符合Pan-shinⅠ模型,幼龄材拟合度较好;组织比量符合y=aebx变异模型;幼龄材和成熟材的界定年限为28～33a之间。     

人工林马尾松木材性质的变异

本文研究了广西人工林马尾松木材性质的变异及幼龄材与成熟材的差异。结果表明 ,幼龄材与成熟材的分界年龄在 14　 16a ,解剖性质在径向上的变异规律为 :射线比量、树脂道比量、胞壁率、胞腔直径、胞壁厚、管胞长度、管胞宽度和晚材壁腔比是自髓心向外呈递增趋势 ,管胞比量和晚材率为递减趋势 ,早材壁腔比和早材腔径比则近似于一条直线。方差分析结果表明 :树脂道比量、胞壁率、胞壁厚、管胞长度和管胞宽度 ,幼龄材与成熟材差异达显著或极显著水平。 5项木材物理力学性质均为成熟材高于幼龄材 ,且均达差异显著水平。木材性质间的相关分析表明 :木材基本密度与管胞长度、管胞宽度、射线比量、树脂道比量、胞壁率呈显著的正相关关系 ,木材气干密度与抗弯强度、抗弯弹性模量、顺纹抗压强度也呈显著的正相关关系     

油松株内幼龄材与成熟材材性的比较研究

本文就中条山油松株内幼龄材与成熟材材性差异的比较研究,讨论对幼龄期划分的依据。根据木材解剖特征、物理力学性质的径向变异规律,确定其幼龄期为14年。随着树干高度的增加,油松木材幼龄期逐渐缩短、株内幼龄材范围及所占断面上的比例变小。株内幼龄材与成熟材材性差异显著。幼龄材管胞长度短、直径小,胞壁薄,微纤丝角度大,生长轮较宽,晚材率低,浸提物含量高,基本密度较大。幼龄材的力学强度远远小于成熟材。     

基于支持向量机(SVM)的班克松人工林成熟材解剖性质的预测

成熟材含量的高低决定木材性质的优劣,合理界定幼龄材与成熟材的分界点,准确预测成熟材材质有利于木材高效加工利用.为了确定人工林班克松的成熟期和预测成熟材解剖性质,采用支持向量机(SVM)界定幼龄材与成熟材的分界点,在此基础上利用幼龄材解剖性质预测成熟材解剖性质.结果表明:人工林班克松幼龄材与成熟材的分界点在树木生长的第18年;成熟期解剖性质明显优于幼龄期,变化较幼龄期平缓;成熟预测误差低、相关性高;预测曲线能够体现解剖性质整体的变化趋势,但对解剖性质测试集突变点及其之后的变化情况表现不足.     

针叶树木材细胞力学及纵向弹性模量的计算--试件纵向弹性模量的预测

依据针叶树木材管胞和射线细胞的结构模型。使用计算机抽样模拟解剖结构参数。以及使用针叶树木材纵向弹性模量计算公式和方法,计算人工林杉木,马尾松幼龄材和成熟材试件纵向弹性模量,计算结果与常温条件下气干试件测定结果十分符合。在试件晚材率和管胞解剖结构参数改变的条件下。计算预测了人工林杉木,马尾松幼龄材和成熟材纵向弹性模量的变化。结果表明：试件纵向弹性模量随晚材率,管胞长度,管胞壁厚度的增加而增加,而试件纵向弹性模量随管胞直径增加而减小。本文提出的纵向弹性模量计算的预测方法,对于运用现代生物技术控制和改变针叶树木材的材质,材性有实际意义。     

中国主要人工林树种幼龄材与成熟材及人工林与天然林木材性质比较研究

本文对中国１０种人工林和４种天然林的幼龄材与成熟材及４个树种的人工林木材与天然林木材的构造特征、化学性质、物理性质、力学性质的３３项材性指标差异进行了比较研究。结果表明,在幼龄材与成熟材之间,在统计上表现出差异显著性的为幼龄材比成熟材生长轮宽,管胞列数多,管胞短,直径小,微纤丝角大,密度小,径向干缩小,差异干缩大,流体扩散性高,抗弯强度、抗弯弹性模量、顺纹抗压强度、径面顺纹抗剪强度、径面抗劈力和冲击韧性低等１５项,即４６％的测试项目差异显著;表明在木材加工和用作结构材时应将幼龄材和成熟材视作两个性质不同的总体来考虑,在培育结构材时应研究如何缩短幼年期或改善幼年期材性。在人工林与天然林木材之间,采取人工林幼龄材性质与天然林幼龄材性质相比,人工林成熟材性质与天然林成熟材性质相比,结果表明,多数性质在统计上差异不显著,只有人工林木材比天然林木材胞壁率小、顺纹抗压强度低、差异干缩大、流体扩散性高等４项,即只有１２％的很少数测试项目差异显著;表明有可能通过人工培育的方法培育出与天然林木材性质相近的木材。     

黄果厚壳桂纤维特性变异规律研究

以黄果厚壳桂(Cryptocarya concinna)为研究对象,通过测量黄果厚壳桂纤维特性,分析对比各项纤维形态在纵向和径向上的变异规律,初步划分幼龄材和成熟材。结果表明:纤维长度为954.46μm,属于中等长度纤维,纤维宽度、腔径、双壁厚、壁腔比、长宽比分别为19.95μm、10.96μm、8.98μm、0.82、47.87。根据有序聚类分析法确定黄果厚壳桂幼龄材和成熟材的年龄界定为第26年。     

北京地区I-214杨树木材解剖特性与基本密度的株内变异及其预测模型

对北京地区Ⅰ—214杨的纤维和导管分子长及宽度、纤维壁厚、组织比量、胞壁率与基本密度和生长轮宽度在株内不同高度上的变异模式及其之间的相关关系进行了全面的测定与分析。结果表明：纤维长、宽及壁厚，导管分子长、弦径和导管比量径向变异由髓心向外迅速递增，而后趋于平缓；而导管个数、纤维与射线比量、胞壁率的径向变异由髓心向外逐渐递减，再趋于稳定。不同高度间的解剖参数(胞壁率除外)差异不显著。基本密度的径向变化是髓心处较大，往外先略减而后快速递增，然后趋于平缓。木材幼龄期为10～12a，幼龄材比成熟材的基本密度低，纤维和导管分子均短与窄、壁薄，纤维和射线比量大、导管个数多、导管比量小，生长轮宽度窄，且两者间的基本密度、纤维和导管分子长度、导管弦径、导管和射线比量差异均达显著水平。生长速度对解剖性质影响不显著，但与木材基本密度呈显著负相关，解剖参数与基本密度关系密切。基本密度和各项解剖参数均与生长轮年龄为极显著相关，可建立模型预测。     

复配碱液处理榆木顺纹压缩应力-应变本构关系

采用复配碱液处理榆木后,对榆木的幼龄材和成熟材顺纹压缩,通过建立的榆木顺纹压缩应力-应变本构关系得出:在榆木顺纹压缩初始阶段,符合线形的弹性虎克定律;在弹塑性阶段,也基本符合线形的力学关系。分析榆木幼龄材在顺纹压缩中体现出较大的差异性、顺纹压缩弹性模量和应力、应变的原因是木材化学组分的降解和抽出;得出复配碱液处理后木材顺纹压缩弹性、弹塑性变化的基本规律,木材在弹塑性阶段呈一段平滑的曲线,细胞壁在此阶段形成褶皱。     

樟树人工林株间株内材性变异及其材性预测的研究

樟树人工林株内纤维长度径向变异由髓心向外递增，而后趋于稳定；木材基本密度髓心处稍大，由髓心向外先稍递减而后递增，再趋于稳定；纤维长度和基本密度性状与生长轮年龄关系模型可用来预测其性状值。樟树木材幼龄期约为7－9a，株内细幼龄材基本密度较成熟材小1．0％－9．9％，株内幼龄材与成熟材基本密度差异多不显著；其浸提物含量幼龄材与成熟材之间差异不显著。纤维长度株内变异系数大于株间，木材基本密度均值和浸提物含量二性状则是株间变大于株内变异。生长速度对樟树木材纤维长度、基本密度、浸提物含量等性状影响不显著。     

Variation Within Trees of Wood Anatomical Properties in Chinese-Fir Plantation and Their Relationship Modeling Equations

A comprehensive analysis on the variation pattern of early- and latewood tracheid morphological parameters along tree (Cunninghamia lanceolata Hook.) height, including length and width, wall thickness, tissue proportion, cell wall percentage, width of growth rings, and on the relationship among them are conducted. The results indicate an initially rapid and then gentle increase of tracheid length and width, thickness of the radial wall and tangential wall of tracheid, area percentage of tracheid from pith to outward, while S2 microfibril angle (Mfa) of tracheid, and rays percentage gradually decrease and then tend to be stable. The variation of all anatomical parameters but earlywood cell wall thickness shows no significance along tree height. The radial variation pattern of width of growth rings is characterized with initially slight decrease followed immediately by a rapid and then much more gentle increase from pith to outward. The delimitation age between juvenile and mature wood is 14-16 years. Com     

Effects of radial growth rate on selected indices for juvenile and mature wood of the Japanese larch

To examine the differences between juvenile and mature wood, 12 aged sample trees from two areas of Nagano Prefecture were harvested; and the radial development of tracheid length, the ring density, and the relation of the radial growth rate (observed by ring width) with some selected indices of ring structure were investigated. The results proved that the radial variation of tracheid length with ring number can be described by a logarithmic formula, and both plantations reached the demarcation of juvenile and mature wood at age 18. With the segmented regression method, we also analyzed radial variation of mean density and found that the demarcation of juvenile and mature wood was at age 15 for sample trees from Saku and at age 21 for those from Yabuhara. By using the results of estimates from juvenile and mature wood based on ring density, we found that high growth rates resulted when producing lower-density wood during the juvenile period, but these rates did not occur during the mature period. The basic reason for this phenomenon is the variation in patterns of earlywood and latewood in juvenile and mature wood, respectively. This result advised us that when managing plantations of Japanese larch it is necessary to take different measurements at different growth periods.     

马尾松人工林管胞长度的株间和株内变异

林木株间变异和株内变异是木材的两个主要变异来源,由于木材性状具有较强的遗传性以及育林措施对木材的可塑性,人们可以培育出材质优异的木材,然而因变异的存在,在如何充分利用木材时却遇到了许多困难。林学家的一个主要目的就是在充分掌握木材变异规律的基础上,采用有效方法提高材质的均匀性。     

Variation in density of Picea sitchensis in relation to within-tree trends in tracheid diameter and wall thickness

The influences of cambial age and ring width on density of Sitkaspruce (Picea sitchensis (Bong.) Carr) were analysed in relationto within-tree trends in tracheid diameter and cell wall thickness.Discs were sampled at breast height from a total of 24 trees,from seven stands at three contrasting sites in Wales, and atbreast height, 30 per cent and 60 per cent total tree heightfrom one of the stands. Across the juvenile wood, ring density decreased with ring numberfrom the pith while radial tracheid diameter increased. Theseoverall trends were considered to be inherent to tree growth,presumably associated with cambial ageing, since they occurredin all trees on all sites. In juvenile wood, density also variedwith site growth rate (as indicated by ring width) at similarcambial age, wider rings being associated with more rapidrateof change in tracheid diameter with ring number and with decreasein tracheid wall thickness. Consequently, on a site having treeswith high growth rate density decreased more rapidly acrossthe juvenile wood, down to a lower minimum value, than on siteswith a slower growth rate. In mature wood, the decrease in densitywith increase in ring width was associated with differencesin both tracheid diameter and wall thickness. Density was slightly(though not significantly) higher at breast height than in comparablerings at 30 per cent total height, associated with significantlythicker tracheid walls at breast height. Changes in radial tracheid diameter (with ring number, or withring width) were associated with greater differences in theearlywood than towards the latewood end of each growth ring,while variations in wall thickness with ring width were associatedwith rate of increase in wall thickness towards the latewoodend. This may account for some previously conflicting reportson influence of silvicultural management on density, for densityis likely to vary with influence of environment on the seasonalcycle of cambial activity. The extent of the juvenile wood as delimited by the inner coreof wide growth rings does not necessarily correspond to theregion of varying tracheid dimensions in Sitka spruce.     

Control of tracheid cross-sectional dimensions in Norway spruce and Scots pine wood raw material

Abstract

Wood properties, including tracheid cross-sectional dimensions, show a large degree of variation. To improve the properties of products made from wood, different methods to control variation have been developed. This study aims to determine the theoretical efficiency of three control strategies: the fractionation of pulped tracheids into earlywood and latewood, the separation of juvenile and mature wood, and sorting of logs according to tree size. The efficiency of each method was studied by first constructing virtual trees from measured tracheid cross-sectional dimensions, then simulating the efficiency of above-mentioned methods. The tracheid dimension data include Norway spruce (Picea abies (L.) Karst.) and Scots pine (Pinus sylvestris L.). The simulations show that separation into earlywood and latewood classes has the highest theoretical efficiency and yields the lowest variances in raw material. Classification into juvenile and mature wood groups is the second most efficient method, and the sorting of logs according to the size class of the tree is the least efficient method. It was also concluded that the variation in cell-wall thickness and radial diameter mainly originates from differences between earlywood and latewood, whereas the variation in tangential diameter mainly originates from differences between mature and juvenile wood.     

油松管胞形态特征的变异

本文研究分析了山西中条山产地油松管胞形态特征的变异。管胞长度自髓心向外,首先迅速增加,13年后管胞长度增加缓慢,20年后保持相对稳定。管胞长度沿树干主轴自基部向上逐渐增加,5.3m高处最长,然后向上变短,树冠区域管胞长度最短。形成层原始细胞长度随着原始细胞年增大,开始递增,达到最大值后又递减。管胞直径、胞壁厚度自髓心向外增加。管胞直径轴向变化由树干基部开始向上增大,然后又减小。管胞长宽比、壁腔比的径向变异与管胞长度的径向变异模式相似。生长轮内管胞长度从早材到晚材,开始减小,然后增加,最小值位于早晚材过渡处。     

Variation pattern of wood properties of naturalCunninghamia lanceolata

In this paper, the variation pattern of wood properties was studied for naturalCunninghamia lanceolata. The mathematical models of property parameters were obtained on tracheid length, microfibril angle, late wood percentage, growth ring width and growth ring density in the radial direction. The interrelation were analyzed between tracheid length and microfibril angle. The result can provide scientific theory basis for wood utilization and early prediction of wood properties.