Effects of Heating Temperature and Moisture on Indirect Gasification of Rubber Wood in Closed Gasifier Chamber

Rural area in Indonesia of which electrification ratio is still low has a strong demand for off-grid electric power supply. On the other hand, Indonesia is a leading natural rubber production country and these rubber wood trees are cultivated in vast plantation farms. A rubber wood tree is woody biomass resource which can be stably supplied because a lot of trees aged more than 25 years are logged and nursery trees are planted constantly. Woody biomass is burned directly as solid fuel and the generated thermal energy can be applied only for room heating or cooking. Otherwise, direct conversion of biomass to electric energy requires a large scale equipment such as a boiler and a steam turbine, whereas gasified woody biomass can be easily handled and can have wide application. A closed gasifier chamber which was kept vacuum and fulfilled with gas yield during gasification was recently developed by the authors for indirect gasification. It was confirmed that generated gas by the gasifier is clean and can be directly used to drive an engine generator to supply electricity. In this study, planer dust of rubber wood is used as gasification feedstock for indirect gasifying in the closed gasifier chamber, and effects of heating temperature and moisture content on gasification performance are discussed to examine characteristics of the closed gasifier chamber in details.

Effects of Secondary Chamber on Gas Yield by Pre-Vacuum Chamber Pyrolysis of Rubber Wood

Global warming awareness criticizes further usage of fossil fuels and insists promotion of renewable energy usage. Additionally, many people in rural areas of developing countries cannot access electricity. To solve this sort of energy crisis including global warming, current authors developed a proto-type of a pyrolysis plant equipped with a prevacuum chamber, which can be used to produce combustible gases for an engine generator in rural areas where people cannot access electricity. The plant is simple and easily maintained in consideration of special conditions that a rural area can receive very few maintenance service, technical assistance, and supply of spare parts. However, gas yield obtained by the proto-type of plant was around 20 wt% of feedstock. One way to enhance gas yield from this proto-type of plant is to utilize reaction of secondary tar cracking. This research work aims to examine possibility of gas yield enhancement keeping a simple structure of the proto-type of plant and using a simple technique of secondary tar cracking. Two tar cracking methods are examined: one is homogeneous tar cracking and the other is heterogeneous tar cracking using catalysis. In the homogeneous tar cracking, pyrolysis gases must be heated up to 650oC to 700oC and in the heterogeneous tar cracking, wood char is used as catalysis, because wood char is byproduct of pyrolysis. It is concluded that the homogeneous tar cracking is quite unlikely in the secondary chamber, but on the other hand, heterogeneous tar cracking using wood char can produce 30 wt% of gas yield from 1 kg of feedstock.

Biological Durability of Heat-Treated Rubber Wood

In this study,the durability of rubber wood(Hevea brasiliensis) which was thermally treated at 170,185,200,and 215℃for 3 h respectively was investigated.The results showed that the durability of heat-treated rubber wood was improved,and the improvement became more obvious with the increase of the treating temperature. When treated at 185℃or lower temperature,the decay resistance of treated wood had no significant improvement.The lowest weight losses were 21.6%and 6.8%after attack by brown rot fungi(Gloeophyllum trabeum) and white rot fungi (Coriolus versicolor) respectively,which were reached by the specimens treated at 215℃.Their resistance to mold fungi was not improved,but the heat-treated wood performed better than untreated wood when both were painted.In field test,the heat-treated specimens exhibited no advantage in termite resistance compared to untreated.

不同热处理条件下橡胶木淀粉含量与抗蠹虫性能关系研究

为克服橡胶木易发生蠹虫危害的缺陷,采用不同热处理温度(90、120、150℃和180℃)和不同热处理时间(2、4 h和6 h)对橡胶木进行热处理,利用分光光度计考察不同温度和时间条件下热处理橡胶木中的淀粉含量变化,并分析蠹虫对橡胶木的蛀蚀程度与淀粉含量之间的关系。结果表明:热处理温度和处理时间对橡胶木中的淀粉含量有显著影响,且随着热处理温度的升高和热处理时间的延长,淀粉含量逐渐下降,从12.79%降至1.25%。在橡胶木抗蠹虫试验中,热改性处理后橡胶木的抗蠹虫效果均优于对照材,且橡胶木淀粉含量越低,其抗蠹虫效果越好。在实际生产过程中,在120℃下处理6 h为生产热处理橡胶木的优化条件,既能刚好维持橡胶木抗蠹虫的最低要求,也能降低热处理过程中木材强度的损失。

Wood Pyrolysis in Pre-Vacuum Chamber

Climate change, global warming, and energy crisis are critical issues to be solved urgently in a global framework. Alternative energy and renewable energy technologies must be quickly developed to be substituted for fossil fuels like oil, gases, and coal. USA, UE, and Japan invested huge budgets to develop biomass renewable energy technology. Their target is to develop a commercial base large-scaled plant. On the other hand, in developing countries, especially in rural areas, people who can access electricity is still less than 70%, To decelerate or prevent global warming and improve electrification in rural areas, a new technology for wood pyrolysis, which requires low manufacturing cost and less maintenance, and of which gases are directly applicable to the gas engine generator, is developed in a laboratory scale. This paper reports the performance of this new plant and effects of several parameters on the performance. It is concluded that the new technology is quite feasible in rural areas, and upgrading of the plant is easily possible.

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。

木材表面原位构筑VMQ树脂增强有机硅橡胶涂层

与有机高分子主链的C-C或C-O键相比,有机硅高分子的Si-O-Si主链具有更佳的柔顺性和更大的键能等,因此具有优异的耐高低温和耐紫外等性能,在生产生活中得到广泛的应用。本文旨在利用无溶剂法在木材表面原位构筑甲基乙烯基硅树脂(VMQ树脂)增强的有机硅橡胶涂层,以实现对木材的保护。以聚甲基氢硅氧烷(PMHS)和端乙烯基聚二甲基硅氧烷(Vi-PDMS)为原料,在Kastredt催化剂的作用下通过加成反应制备加成型有机硅橡胶。同时,系统研究乙烯基MQ树脂(VMQ树脂)对木材表面有机硅橡胶涂层性能的影响。结果表明,VMQ树脂的添加显著提升了有机硅橡胶的硬度以及涂层的耐磨性。向有机硅橡胶中添加16%的VMQ树脂后,LX-A型邵氏硬度19.5增大到34.2,砂纸耐磨损长度从1200 cm增大到2400 cm;木材表面构筑的涂层具有良好的疏水性,水接触角为109.74°。SEM结果表明,VMQ树脂增强的有机硅橡胶涂层在木材表面涂覆均匀,木材的吸水率从88.33%下降到17.93%,具有较好的防水性能。此外,该有机硅树脂疏水涂层还具有较好的耐老化性。

尖芽孢镰刀菌侵染对橡胶木化学组分的影响

用从自然变色的橡胶木上分离出的尖芽孢镰刀菌(Fusarium oxysporum),在28℃侵染橡胶木薄片60 d,发现尖芽孢镰刀菌可以使橡胶木薄片发生变色。以变色后的橡胶木薄片为研究对象,进行红外光谱分析、X射线衍射分析和偏光、荧光显微镜观察。结果表明,红外光谱与X射线衍射分析发现尖芽孢镰刀菌侵染后的橡胶木薄片化学成分有不同程度的变化,纤维素、半纤维素和木质素有微量的降解;偏光和荧光显微镜观察发现经尖芽孢镰刀菌侵染后的橡胶木薄片基本解剖结构没有明显变化,纤维素与木质素的降解也仅少量存在于色素与菌丝处。

橡胶木吸湿/防霉防腐功能改良研究

目的为了改善橡胶木吸湿导致的霉变、虫蛀和腐朽等问题,利用改性剂降低橡胶木的吸湿性能,显著改善防霉防腐性能。方法分别用糠醇、马来酸酐和乙酸酐浸渍处理橡胶木,运用吸湿增重率、动态接触角分析、傅里叶红外光谱(FTIR)分析等方法研究橡胶木的吸湿性能变化;采用空气杂菌、白腐菌和褐腐菌考察其抗生物劣性。结果药剂处理能不同程度地降低橡胶木的吸湿性能,糠醇和马来酸酐处理材的吸湿率可降低13.13%~67.18%,乙酸酐处理材的吸湿率先增加后下降。生物抗性结果显示,糠醇能显著提升橡胶木的防霉抑菌性,4 h处理材对白腐菌的抗性比素材的提升了45.92%,对褐腐菌的抗性提升了16.61%;马来酸酐和乙酸酐对微生物的生长也有一定抑制效果。结论采用马来酸酐、糠醇和乙酸酐浸渍橡胶木降低了游离羟基含量,从而降低了橡胶木吸湿性能,显著改善了防霉防腐性,且糠醇浸渍处理4 h的橡胶木可获得最佳的生物抗性。

三种散孔材植物纤维化学特征的比较

目的以海南橡胶木为原料,对其化学全组分(灰分、综纤维素、酸不溶木素、聚戊糖、α−纤维素、NaOH(1%)抽出物、苯醇抽出物、淀粉和蛋白质)含量进行测定,观察和研究橡胶木的微观结构,并与典型阔叶材杨木和桦木进行对比分析,明确海南橡胶木的化学组分和微观结构特征。方法采用植物显微技术结合化学组分测定的国家标准予以分析。结果海南橡胶木的木素、综纤维素、灰分、聚戊糖、α−纤维素、抽出物与杨木和桦木存在微量差异,其淀粉和蛋白质含量远高于典型阔叶材杨木和桦木;橡胶木纤维的长度为1176.68μm,宽度为21.35μm,长宽比约为55.11,壁腔比为0.49;橡胶木属散孔材,木射线组织呈异型Ⅰ和异型Ⅱ,木纤维具有纤维管胞和角质木纤维,轴向薄壁组织有傍管薄壁组织和离管薄壁组织2种。结论较高的纤维素和较低的木素、苯醇抽出物含量,较大的长宽比及较小的壁腔比,使得橡胶木在制浆过程中所消耗的脱木素和漂白药剂更少,蒸煮时间更短,制浆得率更高,纤维交织能力更强,纤维分布更密,纸张结合强度更高,较为适宜作为制备力学性能优良的纸基包装材料的重要基材。

丁苯橡胶对竹粉/高密度聚乙烯复合材料冲蚀磨损特性的影响

为制备适用于海岸工程领域的高耐冲蚀型木塑复合材料,基于旋转射流技术研究了丁苯橡胶(SBR)对竹粉/高密度聚乙烯(HDPE)复合材料冲蚀磨损特性的影响。结果表明,引入SBR可以提升竹粉/HDPE复合材料的硬度和冲击强度(硬度最大增幅1.3%、冲击强度最大增幅18.8%),并优化竹粉/HDPE复合材料中纤维和基体的两相界面质量。较之未引入SBR的竹粉/HDPE复合材料,引入SBR的竹粉/HDPE复合材料的抗冲蚀性显著提升,其最大冲蚀率发生于冲蚀靶距1.0 cm和冲蚀时间180 s处。较之未冲蚀面,竹粉/HDPE复合材料冲蚀面主要表现出纤维破碎和基体脆性断裂,以及氧含量相对增加和羟基伸缩振动加强等磨损特征。引入SBR不改变旋转射流对竹粉/HDPE复合材料的冲蚀机理。

高温热改性橡胶木的生物耐久性

以水蒸气作为保护气体,在170,185,200和215℃的条件下分别热处理橡胶木3h,对热改性橡胶木的生物耐久性进行研究。结果显示:高温热改性可提高橡胶木的耐腐性,其改善效果随着处理温度的升高而提高,当处理温度为185℃或更低温度时,改善效果不明显。215℃处理3h后,褐腐(密黏褶菌)质量损失率由51.6%降至21.6%,白腐(采绒革盖菌)质量损失率由27.6%降至6.8%。选用烟曲霉、哈茨木霉、产紫青霉和可可球二孢进行防霉试验,结果显示热改性橡胶木的防霉性能与对照相比没有明显的改善;经涂饰后,热改性试材的防霉性能优于未处理材。野外耐久性试验结果显示,高温热改性不能提高橡胶木的防白蚁性能。

处理温度对高温热改性橡胶木物理力学性能的影响

以过热蒸汽为介质常压高温热改性人工林橡胶树木材,处理温度为170、185、200和215℃,处理时间均为3 h。分析了处理温度对热改性橡胶木物理力学性能的影响,结果表明:提高热处理温度,橡胶木的平衡含水率显著降低,降幅为34.33%～62.97%;干缩率显著降低,降幅为3.1%～51.75%(弦向)和2.72%～48.57%(径向);湿胀率显著降低,降幅为37.80%～69.85%(弦向)和28.04%～68.57%(径向);吸水率轻微下降,但不显著;热改性后,橡胶木的尺寸稳定性明显提高。气干密度、全干密度仅在215℃处理时明显下降,其余处理温度变化不显著;弦面硬度先略微增加,后急剧降低,整体呈下降态势;弦、径向局部横纹抗压强度先升高后下降,整体呈增加态势;抗弯强度显著降低,降幅为9.26%～37.52%;抗弯弹性模量有增加,但不显著。

ZCMR法从废物中制取活性炭及在含铬废水处理中应用

采用微波照射－ 氯化锌（ Ｚ Ｃ Ｍ Ｒ） 法从废物中制取锯末活性炭及烤胶废料活性炭，用所得的两种活性炭处理含铬废水，结果表明， Ｚ Ｃ Ｍ Ｒ 法制取的废物活性炭对电镀废水中铬的吸附容量是市售一级粉末活性炭的１ ．７２ ～１ ．８ 倍， 过滤速度是市售活性炭的１ ．６ ～１ ．７ 倍， 极限吸附量达２１ ．５ ～２２ ．５ｍｇ／ｇ ．

改性橡胶木粉/HDPE复合材料结构和力学性能的研究

用硅烷偶联剂A-171和天然橡胶胶乳(MGL-30)改性碱处理后的橡胶木粉。研究了木粉粒径、改性剂和木粉质量分数对橡胶木粉填充HDPE复合材料力学性能的影响,并对复合材料的断面形貌和木粉的表面结构进行了SEM分析。结果表明:木粉粒径、改性剂及木粉质量分数对复合材料力学性能有较大的影响。改性后木粉与基体HDPE的界面粘结强度提高,从而有效地提高了复合材料的力学性能。

热处理橡胶木的有机酸释放量及其对材性的影响

为了改进橡胶木热处理工艺,采用过热蒸汽作为传热介质,进行橡胶木热处理,检测处理过程中,橡胶木释放有机酸的量,并探讨有机酸对材性的影响。结果表明,提高热处理温度,延长高温阶段处理时间,试材释放有机酸量增加;随着有机酸释放量的上升,橡胶木的平衡含水率降低,质量损失率增加,颜色变深,抗弯强度下降,耐腐性改善。

热处理温度对橡胶木物理性质的影响

在170、185、200、215℃四种温度下,分别处理橡胶木3 h,检测处理材的质量损失率、颜色、pH值等。结果表明,随着热处理温度的升高,处理材的质量损失率、色差明显增大,材色加深,明度、pH值、平衡含水率下降。

橡胶木粉填充LLDPE复合材料的结构和力学性能

用橡胶木粉填充线性低密度聚乙烯(LLDPE),研究了酸、碱溶液预处理木粉的效果和硅烷偶联剂(KH 570)、MMA接枝的天然橡胶胶乳(MGL 30)两种改性剂对橡胶木粉表面改性的效果,以及木粉粒径和填充量等对木粉/LLDPE复合材料力学性能的影响,并用SEM对复合材料拉伸断面的形态结构进行了分析。结果表明:木粉的粒径、木粉填充量和改性剂用量对复合材料的力学性能有较大的影响,经碱溶液预处理再用改性剂改性后的木粉能有效地改善木粉与LLDPE的界面粘结强度,提高橡胶木粉/LLDPE复合材料的力学性能。

磷-氮-硼复合阻燃剂处理橡胶木的初步研究

采用水基型磷-氮-硼复合阻燃剂,对炭化及未炭化橡胶木进行浸注处理,分析不同配方的阻燃剂对橡胶木增重率(WPG)、抗弯弹性模量(MOE)和抗弯强度(MOR)的影响。结果表明:不同配方的阻燃剂对未炭化橡胶木的增重率无显著影响,而对炭化橡胶木的增重率有显著影响。不同配方的阻燃剂对未炭化和炭化橡胶木的MOE和MOR均无显著影响,但炭化橡胶木的MOE和MOR明显低于未炭化橡胶木。

橡胶木变色菌和霉菌的研究Ⅰ.菌种的分离,培养和鉴定

本研究对诱发橡胶木材发霉、变色的变色菌和霉菌进行分离、培养和鉴定,共分离到22个分离物,鉴定为10个属,分別隶属于子囊亚门、半知菌亚门和接合菌亚门。本文对Lasiodiplodia(Botrvodiplodia)theobromae和Ceratocvstis spp在木材上的症状和形态进行了描述。有的真菌在橡胶木材上出现属首次报道。