丙烯酸树脂豆基胶黏剂的研究

以丙烯酸树脂作为交联剂,制备共混改性豆基胶黏剂。探讨了助剂加入量、助剂种类、胶液pH值及热压温度对胶合板的胶合强度与耐水性的影响。结果表明:当助剂加入量为胶液的3/1 000、助剂为聚氯化铝、胶液pH值为3.75时,压板工艺为热压时间6 min、热压压力1.1 MPa、热压温度125℃时,胶合板胶合强度为0.74 MPa,符合GB/T9846—2015中Ⅱ类胶合板强度要求。     

胶合工艺对桉/杨Ⅰ类胶合板胶合强度的影响

按树和杨树是种植广泛的人工林树种之一,利用其制造结构胶合板意义大重.通过测定不同热压温度、时间、压力和涂胶量条件下,桉杨混合组坯结构胶合板的胶合强度,发现4个因子对胶合板的胶合强度均影响显著.本试验范围内,较优胶合工艺参数为:热压温度145℃、时间1.5 min/mm、压力0.8 MPa、涂胶量320 g/m2.     

改性大豆蛋白胶黏剂制造杨木胶合板热压工艺

利用单因素试验方法,研究了热压温度、热压时间、热压压力和施胶量对使用改性大豆蛋白胶黏剂制造的杨木胶合板胶合强度的影响规律.结果表明:在100～ 220℃热压温度范围内,随着热压温度的增加,胶合强度显著增大;在35～60 s/mm热压时间范围内,胶合强度随热压时间的增加呈上升趋势,当时间从60 s/mm升至85 s/mm,胶合强度几乎保持一致;热压压力在1.25 MPa时,胶合强度达到最大值;施胶量在130 ～430g/m2热压时间范围内,胶合强度随施胶量的增加呈上升趋势.由此得出最优工艺参数为:热压温度180℃,热压压力1.25 MPa,热压时间60 s/mm,施胶量为310g/m2.     

环氧树脂-水性聚酰胺改性豆粕胶黏剂压制胶合板的研究

本文采用环氧树脂和水性聚酰胺对豆粕进行复合改性制备无醛胶黏剂,对豆粕胶黏剂的性能指标和胶合板的胶合强度进行了研究.通过正交试验得出以下最佳工艺参数:当热压温度为120℃、环氧树脂与水性聚酰胺改性豆粕溶液的质量比为20:80、热压时间600 s时胶合板的胶合强度最高,为0.7628 MPa,达到国家标准GB/T 9846...     

改性豆基蛋白胶黏剂的胶合工艺初探

以杨木单板为试材研究了改性豆基蛋白胶黏剂的胶合性能,采用单因素实验方法,探讨了改性豆基蛋白胶黏剂压制胶合板的胶合工艺。分析了热压温度、热压时间和涂胶量对三层杨木胶合板胶合性能的影响。结果表明:采用改性后的豆基蛋白胶黏剂,在压力为1.4MPa,温度为165℃左右,热压时间为1.4～1.6 min/mm,涂胶量为220g/m~2,压制的杨木胶合板胶合性能较佳且达到Ⅰ类胶合板的标准。     

低密度聚乙烯膜胶合板制备工艺研究

以杨木单板为基材,低密度聚乙烯(LDPE)薄膜为胶黏剂制备木塑复合胶合板,探讨了单位面积上LDPE的质量、改性剂种类及热压工艺对木塑复合胶合板胶合强度的影响。结果表明:经过表面改性的杨木单板制备的胶合板胶合强度优于未改性单板制备的胶合板胶合强度;以KH-550为杨木单板表面改性剂(用量2%),采用121 g/m~2 LDPE薄膜,在温度160℃、时间8 min、压力2.0～2.2 MPa热压工艺条件下,制备的木塑复合胶合板胶合强度符合GB/T 9846—2015中Ⅱ类胶合板要求;表面改性单板表面接触角的检测结果表明,经硅烷偶联剂KH-550处理的木材表面接触角最小,其渗透性较好。     

豆胶的热反应特性及胶合特性分析北大核心

大豆蛋白胶因其可再生、可降解和环保性而受到广泛关注。豆胶的热反应特性和胶合特性研究结果显示:以20℃/min速率升温时,豆胶胶液在157℃时完全固化,在173℃开始降解;胶合板的胶合强度与涂胶量呈线性正相关。按热压温度160℃、热压时间80s/mm、压力1.6MPa、双面涂胶量450g/m2的工艺制备豆胶胶合板,其湿态胶合强度为0.78 MPa,满足GB/T 9846.3-2004《胶合板第3部分:普通胶合板通用技术条件》中Ⅱ类胶合板的要求。     

豆胶的热反应特性及胶合特性分析

大豆蛋白胶因其可再生、可降解和环保性而受到广泛关注。豆胶的热反应特性和胶合特性研究结果显示:以20℃/min速率升温时,豆胶胶液在157℃时完全固化,在173℃开始降解;胶合板的胶合强度与涂胶量呈线性正相关。按热压温度160℃、热压时间80s/mm、压力1.6MPa、双面涂胶量450g/m2的工艺制备豆胶胶合板,其湿态胶合强度为0.78 MPa,满足GB/T 9846.3-2004《胶合板第3部分:普通胶合板通用技术条件》中Ⅱ类胶合板的要求。     

竹材苯酚液化及胶黏剂制备工艺

采用单因素试验和正交试验研究了竹材加工剩余物的苯酚液化工艺,并进一步研究了竹材苯酚液化产物-甲醛树脂胶黏剂(BPF)的制备工艺和性能。试验结果表明:竹材苯酚液化过程中,液化温度对液化效果的影响最为显著,其次是液比和液化反应时间,催化剂用量2%~4%范围内对液化效果影响不大。竹材加工剩余物苯酚液化的优选工艺为:液固比值3.5、催化剂用量4%、液化温度145℃、液化时间60 min;在此工艺下竹材液化率为99.1%。胶黏剂制备过程中,竹材苯酚液化物与甲醛溶液(甲醛质量分数为37%)的合理质量比为100∶164.8~199.5,其中以100∶182.1较佳。BPF的固化温度低于普通酚醛树脂胶黏剂(PF),因而可在较低温度下固化良好,在130℃或140℃热压温度条件下,用其制备的胶合板的胶合强度均比较理想,热压温度为140℃时的试验结果更佳。     

4A分子筛改性阻燃胶合板的研制

用4A分子筛改性脲醛树脂、BL阻燃剂处理杨木单板,通过正交试验设计,制备阻燃胶合板并检测其胶合强度及阻燃性能。结果表明,分子筛可提高阻燃胶合板的胶合强度,分子筛加入胶黏剂中对阻燃胶合板的阻燃性能影响不大。分子筛改性阻燃胶合板制造的优化工艺为阻燃剂浓度10%、分子筛量4%、涂胶量380g/m2、热压温度120℃。     

刨花形态对竹材自生胶合刨花板性能的影响

利用半纤维素酶/漆酶协同处理3种不同类型的竹刨花,热压制备竹材自生胶合刨花板,研究不同刨花形态对刨花板物理力学性能的影响.结果表明:刨花形态对竹材自生胶合刨花板主要物理力学性能有显著影响,3种刨花形态中,4～16目的细刨花性能最佳,16目以上碎刨花作为填料加到大刨花中有利于提高刨花板弹性模量,减小吸水厚度膨胀率.该结论为进一步研究刨花形态与竹材自生胶合刨花板物理力学性能的关系提供了理论基础.     

无胶胶合板试验研究

以活化剂浓度、热压时间及含水率等工艺参数为因子,用正交试验法对无胶胶合板的制造工艺进行研究。结果表明,影响无胶胶合板胶合强度的主要因素是活化剂浓度,热压时间、含水率为次要因素,同时还得到了较优的工艺参数。     

麦秸无胶碎料板制备工艺研究

以麦秸碎料为主要原料,采用漆酶水浴与干法两种不同处理方法压制麦秸无胶碎料板,研究热压温度、热压压力和热压时间对板材物理力学性能的影响。试验结果表明:影响麦秸无胶碎料板物理力学性能的主要因素是热压温度;水浴处理方法压制碎料板的物理力学性能优于干法压制的碎料板;漆酶水浴处理方法较优的热压工艺参数为漆酶用量43.6U/g,含水率10%,热压温度170℃,热压压力3~4MPa,热压时间20~25min。     

Influence of pressing parameters on mechanical and physical properties of self-bonded laminated beech boards

Abstract

Five-ply self-bonded boards were obtained by pressing beech veneers parallel to the grain without additional adhesives, steam or pre-treatment. Fifteen different combinations of pressing parameters were tested, including temperature (200°C, 225°C and 250°C), pressure (4, 5 and 6 MPa) and pressing time (240, 300 and 360 seconds). Due to severe pressing conditions, the new product showed a higher density and different properties compared to a conventionally glued laminated wooden board. The self-bonding quality was assessed through dry shear strength tests, through a three-point bending test and a water-soaking test at 20°C. The dimensions in the cross section of the boards were measured after soaking in water. Results show that the choice of pressing parameters affects all the mechanical and physical properties tested. A statistical analysis revealed that the pressing temperature is the most influential parameter. Boards pressed at 200°C delaminated rapidly in water, whereas boards pressed at 225°C delaminated only at core-positioned layers after 48 hours and boards pressed at 250°C did not delaminate at all in water. Compared to panels pressed at lower temperatures, boards pressed at 250°C had the highest density, a higher shear and bending strength and a lower water absorption.     

Browsing Damage on Pine (Pinus sylvestris and P. contorta) by a migrating moose (Alces alces) Population in Winter: Relation to Habitat Composition and Road Barriers

In Scandinavia, moose (Alces alces L.) sometimes cause severe browsing damage to economically-important pine. Moose-vehicle accidents have spurred construction of fences along roads, and these may interfere with moose migration between summer and winter ranges, or the road alone may be a barrier. If this happens and moose build up along roads, landowners may suffer economically. Therefore, this study investigated whether roads, fences or other factors influence the use of young pine stands by moose. Eighty stands along roads in northern Sweden were evaluated in which individually-browsed branches were counted on 9972 pines. Moose browsing was not significantly related to birch (Betula pendula Roth, B. pubescens Ehrh.) density, nor did it differ between pines (Pinus contorta Douglas or P. sylvestris L.). However, increased pine density, site productivity and proximity to a highway were associated with increased browsing. Further large-scale studies are needed to understand moose habitat selection and the effects of roads.     

Effects of Root Freezing on the Physiology and Growth of Picea glauca,Picea mariana and Pinus banksiana Seedlings Under Different Soil Moisture Regimes

The root systems of 2-yr-old Picea glauca, Picea mariana and Pinus banksiana seedlings were submitted to various frost temperatures during an artificial frost to induce different levels of root damage. Frost-damaged and control seedlings were placed in a greenhouse under high and low soil moisture regimes. Seedling growth and physiology were evaluated periodically. Seedling survival was reduced when root damage reached levels of 60-80%. Root systems of all three species showed partial to total recovery by the end of the experiment. In general, root freezing damage caused reductions in seedling growth, with these reductions becoming less significant over time. Root damage had little to no effect on black spruce and jack pine seedling physiology, while white spruce CO 2 uptake decreased with increasing root damage. Shoot nitrogen content of all three species decreased slightly with increasing root damage.     

Stand Structure in Pine,Spruce and Deciduous Forests: A Comparison Between Finnish and Russian Karelia

This study investigated the stand structure in pine, spruce and deciduous forests in the border district of Finland and Russia. A total of 46 mature forest stands was selected as pairs, the members of each pair being as similar as possible with respect to their forest site type, age, moisture and topography. The stands were then compared between the two countries by means of basal areas and number of stems. The proportions of dominating tree species were 2-12% lower, and correspondingly the proportions of secondary tree species higher, in Russian forests. The density of the forest stock was also higher in each forest type in Russia. The forests in the two countries differed most radically in terms of the abundance of dead trees. The amount was two to four times higher in Russian deciduous and spruce forests, and in pine forests the difference was 10-fold. The stand structures indicated that Russian coniferous stands, in particular, were more heterogeneous than intensively managed pine and spruce stands in Finland.     

Growth and Terminal Bud Formation in Picea abies Seedlings Grown with Alternating Diurnal Temperature and Different Light Qualities

The root collar diameter and the height:diameter ratio are of particular importance in container-grown seedlings where a high density in the containers may produce spindly seedlings. Temperature regimes and light quality are known to affect plant growth. The aim of this study was to identify responses in Picea abies (L.) Karst. seedlings grown with light providing different red:far-red ratios and under temperature regimes with alternating day (DT) and night temperature (NT) from negative (DT < NT) to positive (DT > NT) difference (DIF) between DT and NT. Experiments were conducted in controlled environment chambers and in a daylight phytotron. Only limited thermoperiodic responses appeared in P . abies seedlings with respect to seedling height and dry weight accumulation. The formation of terminal buds, however, was clearly delayed in seedlings grown at negative DIF. The results indicate a requirement for day extension light that is high in far-red, to prevent terminal bud formation under natural short-day conditions. An extended study should be conducted to clarify the minimum level of light intensity and the optimal light quality needed to prevent terminal bud formation under natural short-day conditions.     

CAD与建筑设计的关系

本文分析了CAD在设计中引起的正面和负面影响,并进行了系统的阐述,从而使设计者在应用中能够保持客观的态度。     

Natural Regeneration in Clear-cuts: Effects of Scarification,Slash Removal and Clear-cut Age

The effects of soil scarification (mounding), slash removal and clear-cut age on the natural regeneration in clear-cuts was evaluated using data from four sites in southern Sweden. The treatments were carried out during a good seed and establishment year for birch ( Betula pubescens Ehrh. and B. pendula Roth). Scarification had the strongest positive effect on the density of naturally regenerated seedlings, especially in birch, but also in pine ( Pinus sylvestris L.) and spruce [ Picea abies (L.) Karst]. Slash removal had a positive effect on birch density. No statistically significant effect of clear-cut age was found. In addition, no statistically significant interactions between clear-cut age and scarification or slash removal were found. The ingrowth of field vegetation was the fastest in areas that were not scarified, less rapid in areas scarified on old clear-cuts, and the slowest after scarification in fresh clear-cuts. In conclusion, it may be possible to control the density of birch during a good establishment year for birch. If birch is desired, the best combination of treatments is to remove the slash and scarify; otherwise, these treatments should be avoided.