Two-Stage Hydrogenation Modification of C_9 Petroleum Resin over NiWS/γ-Al_2O_3 and PdRu/γ-Al_2O_3 Catalysts in Series

Hydrogenation modification is one of the most important ways to produce high-quality petroleum resin. The col- orless C9 petroleum resin （CgPR） was obtained by two-stage catalytic hydrogenation over NiWS/？-A1203 catalyst and PdRu/ y-A1203 catalyst connected in series. Via the hydrogenation reaction, aromatic rings in C9PR were converted to alicyclic rings, and its color was reduced from Gardner color grade No. 11 to Gardner color grade No. 0. The optimum Ni/W atomic ratio was found to be close to 0.23, while the optimum Pd/Ru atomic ratio was close to 3.80. The TEM results showed that the morphology and size of sulfide or metal particles of the two kinds of catalysts remained almost unchanged after the reac- tion was carried our for 1 204 hours, attesting to their good catalytic stability.

Tuning the properties of Ni-based catalyst via La incorporation for efficient hydrogenation of petroleum resin

The hydrogenation of petroleum resin(PR)is an effective process to prepare high value-added hydrogenated PR(HPR).However,the preparation of non-noble metal-based catalysts with high catalytic activity for PR hydrogenation still remains a challenge.Herein,a La promoted Ni-based catalyst is reported through the thermal reduction of quaternary Ni La Mg Al-layered double hydroxides(Ni La Mg Al-LDHs).The incorporation of La is beneficial to the reduction and stability of Ni particles with reduced particle size,and the increased alkalinity effectively mitigates the breakage of molecular chains of PR.As a result,the La promoted Ni-based catalyst exhibits high catalytic activity and excellent stability for PR hydrogenation.A hydrogenation degree of 95.4%and 96.1%can be achieved for HC_(5)PR and HC_(9) PR with less reduced softening point,respectively.Notably,the hydrogenation degree still maintains at 92.7%even after 100 hours’reaction,much better than that without La incorporation or prepared using conventional impregnation method.

A Quantum Chemistry Study on Structural Properties of Petroleum Resin

The geometries of resins with single-layer （SG）, double-layer （DG） and triple-layer （TG） were calculated with the quantum chemistry method. The geometries and net charges of atoms were obtained. The calculated average distances between layers were 0.5348 nm and 0.5051 nm and the action energies were -9.6355 kJ/mol and -32.2803 kJ/mol for resins DG and TG, respectively. Higher electronegative polar atoms can easily form hydrogen bonds with hydrogen atoms of other resin molecules, resulting in resin aggregates. The minimum cross-sectional diameters of resin molecules are too large to enter the pores of zeolite, so they are likely to crack on the surface of zeolite.

Study on Preparation of Waterproofing Agent for Mineral Wool Board from Modified C_9 Petroleum Resin

The modified petroleum resin emulsion prepared from the C9petroleum resin was modified with maleic anhydride.The effects of maleic rosin and maleic anhydride addition level,the modification time and the alkali liquor on the properties of the emulsion were discussed.The results showed that the optimum process conditions covered:a maleic anhydride mass fraction of 1.5%,a maleic rosin mass fraction of 10%,a KOH mass fraction of 1%,a petroleum resin modification temperature of 200℃,a petroleum resin modification duration of 3 h,and a modified petroleum resin emulsion/wax emulsion mixing ratio of 1:1.The particle size of modified petroleum resin emulsion prepared under these conditions was equal to 104.166μm.

Highly Active and Stable Ni_2P/SiO_2 Catalyst for Hydrogenation of C_9 Petroleum Resin

Catalytic hydrogenation is an appropriate method for the improvement of C9 petroleum resin（C9PR） quality. In this study, the Ni2P/SiO2（containing 10% of Ni） catalyst prepared by the temperature-programmed reduction（TPR） method was used for hydrogenation of C9 petroleum resins. The effect of reaction conditions on catalytic performance was studied, and the results showed that the optimum reaction temperature, pressure and liquid hourly space velocity（LHSV） was 250 ℃, 6.0 MPa, and 1.0 h-1, respectively. The bromine numbers of hydrogenated products were maintained at low values（250 mg Br/100g） within 300h, showing the high activity and stability of Ni2P/SiO2 catalyst. The fresh and spent catalysts were characterized by X-ray diffraction（XRD）, BET surface area（BET） analysis, scanning electron microscopy（SEM）, transmission electron microscopy（TEM）, Fourier transform infrared（FTIR） pyridine adsorption, and X-ray photoelectron spectroscopy（XPS）. Compared with the traditional sulfurated-Ni W catalysts, Ni2P possessed globe-like structure instead of layered structure like the active phase of Ni WS, thereof exposing more active sites, which were responsible for the high activity of Ni2P/SiO2 catalyst. The stability of Ni2P/SiO2 catalyst was probably attributed to its high sulfur tolerance, antisintering, anti-coking and carbon-resistance ability. These properties might be further ascribed to the special Ni-P-S surface phase, high thermal stability of Ni2P nanoparticles and weak surface acidity for the Ni2P/SiO2 catalyst.

玉米秸秆焦油制备生物沥青的性能研究

随着大规模高等级公路建设和养护维修工程的不断推进,沥青材料的需求量逐渐攀升。随着化石资源的消耗,寻找一种能够替代石油沥青的材料已成为道路工程领域的迫切需求。本文以玉米秸秆焦油为原料,对其进行树脂化处理,制备生物沥青。基于BOX-Behnken响应面分析,以树脂得率为评价指标,确定了树脂合成的最佳工艺条件为:酚醛摩尔比为0.8,反应时间为125 min,秸秆焦油添加量为10%。结果表明:随着树脂化产物的增加,生物沥青的针入度也随之增大,且均高于70#石油沥青。B-PF生物沥青延度随掺量增加呈先升高后降低趋势;但H-PF生物沥青延度随掺量的增大而减小。提高生物沥青掺量可使软化点降低。H-PF生物沥青在10%掺量下延度及软化点低于70#石油沥青,而掺量达到20%时,所制备的生物沥青的软化点和延度皆低于70#石油沥青。

接枝石油树脂提高热熔膜与不锈钢的界面粘接力

在海缆、冻土等环境下,通讯光电缆要求使用高耐腐蚀的金属/塑料复合带,但工业上还存在不锈钢/塑料复合带界面难粘接的难题。文中通过熔融接枝法成功制备了C_(5)及C_(9)石油树脂接枝马来酸酐(C_(5)-g-MAH,C_(9)-g-MAH),将其引入乙烯-丙烯酸共聚物/线型低密度聚乙烯(EAA/LLDPE)热熔膜并与不锈钢基板热贴合,当C_(5)-g-MAH的用量为30 phr时,不锈钢/塑料复合带的剥离强度最优,在泡水测试前后分别达到了28.6 N/cm与15.2 N/cm。接触角测试表明,C_(5)-g-MAH可有效降低EAA/LLDPE热熔膜与不锈钢基板间的表面张力,促进热熔膜在金属表面的贴合。通过差示扫描量热分析、熔体流变行为分析发现,C_(5)-g-MAH可以与EAA/LLDPE热熔膜有效地相容,同时降低热熔膜的熔融温度、活化分子链段,提高对不锈钢表面浸润性的同时增加粘接位点,使得热熔膜与不锈钢基板的界面粘接力大大提升。

C_(5)石油树脂用量对天然橡胶胶料性能的影响

研究C_(5)石油树脂用量对天然橡胶(NR)胶料性能的影响。结果表明:随着C_(5)石油树脂用量的增大,NR胶料的邵尔A型硬度、定伸应力、拉伸强度、拉断伸长率和交联密度减小,但加入40份C_(5)石油树脂的NR胶料的拉断伸长率仍达654%,表明其弹性仍较好;加入C_(5)石油树脂的NR胶料的损耗因子(tanδ)-温度曲线仅出现单个损耗峰,即C_(5)石油树脂与NR的相容性好;随着C_(5)石油树脂用量的增大,NR胶料的tanδ峰值减小,玻璃化温度向高温方向移动,有效阻尼温域拓宽,阻尼性能明显提升;未加入C_(5)石油树脂的NR胶料的断面较为粗糙,加入C_(5)石油树脂的NR胶料的断面较平滑。

抗氧剂对石油树脂性能的影响

采用共混的方式制备了一系列添加抗氧剂的石油树脂,通过红外光谱仪、色度仪以及热重分析仪进行表征,并对石油树脂的抗老化性能进行评价。结果表明:温度的升高会促进石油树脂的老化,抗氧剂的加入能够一定程度抑制石油树脂的老化;添加抗氧剂B 215的石油树脂抗老化性能与C 100-W接近;抗氧剂B 215能够明显改善石油树脂的耐热性能。

兼具加氢和脱硫活性的富含Ni^(δ+)非晶态NiP@γ-Al_(2)O_(3)催化剂的构筑及其用于石油树脂加氢的性能研究

C_(9)石油树脂(C9PR)是由乙烯裂解副产物C_(9)馏分聚合而成的热塑性树脂,经加氢改性后可以制得色度浅、抗氧化稳定性高、相容性好的高附加值氢化石油树脂(HC9PR)。但C9PR分子量大、空间位阻高且原料中含有硫化物等杂质易使催化剂中毒失活,因此加氢难度极大。为了同时实现C9PR的加氢和脱杂,采用化学还原法结合球磨法制备了非晶态NiP@γ-Al_(2)O_(3)催化剂。表征结果显示,该催化剂具有较大的比表面积、富含Ni^(δ+)活性物种、较多的活性位数量,并对C==C键具有较强的吸附能力。对其进行C9PR加氢性能评价,结果显示非晶态Ni P@γ-Al_(2)O_(3)催化剂表现出优异的加氢活性(加氢度98.35%)和脱硫活性(硫含量从122.80μg/g降低至8.00μg/g),明显优于利用程序升温还原法结合球磨法制备的不同晶型磷化镍催化剂。此外,经过连续100 h的反应,该催化剂仍能保持较高的加氢度,表明其具有良好的稳定性。

苯乙烯-丁二烯-苯乙烯嵌段共聚物/橡胶粉/碳九石油树脂复合改性高黏沥青的黏附性

为了改善高黏改性沥青与集料之间的黏附性,制备了基于碳九石油树脂、苯乙烯-丁二烯-苯乙烯嵌段共聚物和橡胶粉的高黏改性沥青(HVAM-2),采用滴定法测定了其与集料之间的接触角并计算出黏附功。通过冻融劈裂试验、浸水飞散试验和汉堡车辙试验进一步验证了HVAM-2混合料的黏附性。结果表明,碳九石油树脂、苯乙烯-丁二烯-苯乙烯嵌段共聚物和橡胶粉三种材料在沥青中形成的网格结构能够大幅度提高沥青的黏附性,有效改善沥青与集料之间的黏接能力;相比于基质沥青,HVAM-2的黏附功提高了72.9%,且HVAM-2沥青混合料具有良好的水稳定性。

超级电容器用活性炭的研究进展

简述了超级电容器的工作原理和超级电容炭的市场情况,分析了植物类、石油焦类、树脂类不同原料制备电容炭(无定型粉末炭)的性能特点及制备工艺,介绍了煤焦油沥青基球形活性炭和煤液化沥青球形活性炭的研究进展,对比了无定型粉末活性炭与球形活性炭的性能优劣,最后对煤液化沥青球形活性炭用于超级电容器的优势及推广应用进行了展望。

C_(5)/C_(9)共聚石油树脂热聚合成工艺影响因素分析

为了得到浅色优质C_(5)/C_(9)共聚石油树脂,本文以C_(5)馏分、双环戊二烯(DCPD)和C_(9)馏分为原料,在原料配比C_(5):(DCPD):C_(9)=350ml:350ml:200ml时,详细考察了反应温度和反应时间对共聚石油树脂的收率、软化点和色度的影响。结果表明:当反应温度为240~245℃时,反应时间为7~8h,可得色度为4#左右的优质石油树脂,并且石油树脂的收率高达60%以上。

黏层用C_(9)石油树脂/SBR复合改性乳化沥青性能研究

采用C_(9)石油树脂和SBR胶乳制备高性能复合改性乳化沥青,通过三大指标试验、高温和低温流变试验评价了复合改性乳化沥青的宏观服役性能,借助激光粒度分析仪、荧光显微镜和红外光谱仪分析复合改性乳化沥青的储存稳定性和相容性,揭示C_(9)石油树脂/SBR复合改性剂对乳化沥青的改性机理。结果表明,C_(9)石油树脂提高了乳化沥青的力学强度和高温抗变形能力,而SBR胶乳明显改善乳化沥青低温抗裂性能,蠕变劲度最大降低30.4%。制备的C_(9)石油树脂/SBR复合改性乳化沥青储存稳定性良好,C_(9)石油树脂和SBR胶乳对乳化沥青的复合改性机理为物理混溶,C_(9)石油树脂的掺量不高于8%。

氢化石油树脂对流延聚丙烯薄膜性能的影响

本文重点研究氢化石油树脂加入流延聚丙烯薄膜后,薄膜性能的变化和改善。不同含量的氢化石油树脂(C9)被加入聚丙烯薄膜,其质量分数控制在0~20%。研究表明,氢化石油树脂的质量分数达到20%,流延薄膜的水汽透过率下降41.3%。薄膜的纵横向拉伸强度与氢化石油树脂添加量之间影响不大,而纵向拉伸强度逐渐下降。氢化石油树脂加入,会大幅度减小雾度,但对透光率影响较小。随着氢化石油树脂的质量分数增加到20%,热封温度从172℃降低到166℃。

水性石油树脂乳液的制备及应用研究进展

综述了石油树脂乳液的机械乳化法和相反转乳化法两类制备方法。重点介绍了石油树脂乳液的应用领域和国内外市场上石油树脂乳液的牌号及其应用方向,指出改性石油树脂乳液的研究是其应用于水性胶黏剂和造纸施胶剂的关键方向。

C9PR加氢催化剂孔道要求及其制备的研究进展

综述了适合于C9石油树脂(C9PR)加氢催化剂孔道结构的要求、孔道结构的制备及调节方法,并提出需加快对C9PR加氢催化剂孔道结构的研究。

喷洒型彩色沥青的制备

以基础油、苯乙烯-丁二烯-苯乙烯(SBS)和石油树脂C9为原料,以乙酸乙酯和溶剂油为复合溶剂,制备了喷洒型彩色沥青,并对其性能进行了评价。结果表明:当SBS和石油树脂C9加入质量分数分别为9%,45%时,制备的机动车道用70号彩色沥青可满足GB/T 32984—2016要求;当乙酸乙酯和溶剂油溶剂质量比为1∶9,配制溶液中彩色沥青质量分数为50%,白云石粉加入质量分数为50%时,制备的喷洒型彩色沥青黏度小于1.0 Pa·s,干燥时间短于60 min,且具有良好的黏结性、耐磨性、不透水性和低温柔性,可达到易喷洒、短期开放交通的效果。

破乳剂在石油树脂碱洗过程中的实例应用

石油树脂生产碱洗系统经常沉降大量的碱泥,且乳化问题严重。若不解决碱泥及破乳问题,树脂中的水分将腐蚀后续的管线配件,而且乳化影响碱洗罐压差,严重时需停机检修。基于此,考察了多种破乳剂在碱洗过程中的破乳、脱油能力,结果表明SGR1710破乳剂碱洗后油相中没有W/O乳状液,水相中没有O/W乳状液。未加破乳剂前废水化学需氧量(COD)>3000mg/L,油水分层速度>4h且界面处有白色乳化层;加入破乳剂后SGR1710废水COD在400mg/L左右,油水分层速度<15min且油水界面齐无乳化层。

胶粉石油树脂复合改性沥青抗车辙性能研究

为研究石油树脂对胶粉改性沥青抗车辙性能的影响,设计了不同胶粉和石油树脂改性剂掺量,制备了胶粉石油树脂复合改性沥青,考虑了未老化和短期老化两种沥青老化状态,分别测试了复合改性沥青的剪切流变特性和蠕变恢复特性。研究发现,随着胶粉含量的增加和石油树脂的掺入,复合改性沥青的抗车辙性能持续得到改善,同时方差分析结果也证明了其改善效果。相比基质沥青,复合改性沥青车辙因子值的提高幅度最高可达近5倍,蠕变恢复率的提高幅度最高可达近10倍。因此采用这两种改性剂生产的沥青材料可保证路面在高温下不易发生车辙。根据多重应力蠕变恢复试验结果,较高的胶粉掺量在弹性性能方面具有更好的抗车辙性。进一步添加石油树脂也会显著降低不可恢复蠕变柔量值。虽然石油树脂的掺入对改性沥青的蠕变恢复率并没有明显的积极影响,但考虑到一些潜在的试验误差,在试验层面总体上可认为石油树脂能够有效改善沥青弹性性能。