Fabrication and Characterization of Diatomite-supported Activated Carbon Functional Ceramic

Using porous diatomite ceramic as carrier and phenolic resin as carbon precursor, the activated carbon functional ceramic with the activated carbon fixed into porous ceramic was prepared by the impregnation load phenolic resin, carbonization and activation isolated air. The influences of impregnation, curing, carbonization, activation etc. on the material property were discussed. The iodine value, SEM, elemental analyzer, BET and spectrum analysis chart were used to characterize the microstructures and performance of material at different conditions. The results showed that the excellent comprehensive property of activated carbon functional ceramic was gained when it adsorbed phenolic resin in 4 h under vacuum condition at curing temperature of 150 ℃ for 0.5 h and carbonization temperature of 600 ℃ for 1.0 h, and then put into 25wt% KOH for 4.0 h at activation temperature of 700 ℃ for 1.5 h. The iodine value is 176.9 mg/g, the specific surface area can reach 86.3 m2/g and the yield of carbonization is 50.48%.

Studies and Characterisations of Activated Carbons Used for Carbon/Carbon Supercapacitors

Activated carbon was fabricated by using oil asphalt as carbon source, KOH as activator. The samples were analyzed by N2 adsorption, scanning electron microscopy （SEM）. Cyclic voltammetry and galvanostatic charge-discharge were used to characterize the electrochemical performance of the samples. The results showed that the pore size was mainly in the range of 0.5-9.0 nm. Supercapacitors based on the sample AC （Activated carbon） have low ESR and excellent power property.

Study on Activated Carbon for Electrode Material

Activated carbon （AC） was fabricated by Coconut shell as carbon source, KOH as activator. Cyclic voltammetry and galvanostatic charge-discharge were used to characterize the electrochemical performance of the samples. The results showed that： Supercapacitors based on the sample AC-3 have low Equivalent series resistanceb （ESR） and excellent power property.

Study on Electrode Material for Carbon Based Double-layer Capacitors

Activated carbon （AC） was fabricated by using phenolic resin as carbon source, silica gel as inorganic template, KOH as activator. The samples were analyzed by N2 adsorption, scanning electron microscopy （SEM）. Cyclic voltammetry and galvanostatic charge-discharge were used to characterize the electrochemical performance of the samples. The results showed that the pore size was mainly in the range of 0.5 9.0 nm. Supercapacitors based on the sample AC-3 have low equivalent series resistanceb （ESR） and excellent power property.

Electrospun porous carbon nanofibers derived from bio-based phenolic resins as free-standing electrodes for high-performance supercapacitors

Phenolic resins were employed to prepare electrospun porous carbon nanofibers with a high specific surface area as free-standing electrodes for high-performance supercapacitors.However,the sustainable development of conventional phenolic resin has been challenged by petroleum-based phenol and formaldehyde.Lignin with abundant phenolic hydroxyl groups is the main non-petroleum resource that can provide renewable aromatic compounds.Hence,lignin,phenol,and furfural were used to synthesize bio-based phenolic resins,and the activated carbon nanofibers were obtained by electrospinning and one-step carbonization activation.Fourier transform infrared and differential scanning calorimetry were used to characterize the structural and thermal properties.The results reveal that the apparent activation energy of the curing reaction is 89.21 kJ·mol–1 and the reaction order is 0.78.The activated carbon nanofibers show a uniform diameter,specific surface area up to 1100 m^(2)·g^(-1),and total pore volume of 0.62 cm^(3)·g^(-1).The electrode demonstrates a specific capacitance of 238 F·g^(-1)(0.1 A·g^(-1))and good rate capability.The symmetric supercapacitor yields a high energy density of 26.39 W·h·kg^(-1)at 100 W·kg^(-1)and an excellent capacitance retention of 98%after 10000 cycles.These results confirm that the activated carbon nanofiber from bio-based phenolic resins can be applied as electrode material for high-performance supercapacitors.

有机胺改性树脂基球形活性炭对二氧化碳的吸附行为

以球形结构的固废离子交换树脂为原料,经CO_(2)活化、酸洗处理制得具有较高比表面积和较大中孔孔容的树脂基球形活性炭(HRSAC),然后在其表面负载聚乙烯亚胺(PEI)制得吸附材料PEI-HRSAC。系统考察了PEI负载量和吸附温度对CO_(2)吸附性能的影响,结果表明,在活化温度为950℃、活化时间为1 h的最佳活化工艺条件下,所制得的树脂基球形活性炭经酸洗处理后其比表面积为1365 m^(2)/g,中孔孔容为2.04 cm^(3)/g,中孔孔径主要分布在10~40 nm;PEI-HRSAC吸附材料对CO_(2)的吸附性能随吸附温度和PEI负载量的升高先增大后减小;当PEI负载量为65%、吸附温度为75℃时,PEI-HRSAC吸附材料对CO_(2)的吸附量最高,约为4.09 mmol/g,在经过4次循环吸/脱附后吸附量仍保持在较高水平(3.66 mmol/g)。

一步炭化-活化法制备球形活性炭及其储氢性能研究

氢能是一种清洁高效的能源,但缺乏高效的氢气储运方式,因而制约了氢能产业的发展。以强酸性聚苯乙烯树脂为原料,KOH为活化剂,通过一步炭化-活化法制备了多孔树脂基球形活性炭,并对样品进行了表征和储氢性能研究。实验结果表明,KOH质量分数为30%、炭化温度为750℃时,制备的球形活性炭比表面积为2158m^(2)/g,总孔容为1.12cm^(3)/g。该样品综合储氢性能最优,在温度-196℃、压力1MPa条件下,质量储氢密度可达3.14%,体积储氢密度为11.47kg/m^(3)。

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。

树脂基防隔热一体化热防护复合材料高温性能演变分析

采用溶胶-凝胶-常压干燥的方法,以耐热杂化酚醛树脂(PF)为基体,复合碳纤维编织物(CF)制备树脂基防隔热一体化热防护复合材料(PF/CF-HT01)。利用热分析(TG)、电子万能试验机研究材料热稳定性和高温力学性能,利用氧乙炔装置研究材料耐烧蚀性能,利用扫描电子显微镜(SEM)、X线衍射仪(XRD)研究材料微观结构演变过程。结果表明:空气中树脂基体的初始分解温度为387.3℃,最大分解温度为644.7℃,800℃时残炭率为13.8%;复合材料初始分解温度为405.3℃,800℃时残炭率为42.8%;复合材料常温压缩强度最大为542.6 MPa,经1 000℃原位热处理30和60 s后的最大压缩强度分别为166.2和149.9 MPa。复合材料具有良好的防隔热一体化性能,其线烧蚀率可达0.039 mm/s,单次热考核结束时背温低于100℃、继续热传导后最高背温低于200℃。高温作用下材料快速陶瓷化形成致密的SiO2和BN瓷化层,赋予材料突出的耐烧蚀抗冲刷性能,而底层仍然保留着多孔结构使得材料保持较好的隔热性能。

油茶果壳生物基材料研究进展及展望

油茶作为木本食用油料树种在南方各省被广泛种植,其加工剩余物油茶果壳若未合理有效利用,将对空气、水体等生态造成污染。油茶果壳富含中孔结构,用其制备活性炭,可用于吸附或电池、电极与电容器领域;油茶果壳去除木质素得到的综纤维素,可制备综纤维素膜材料或纳米纤维素膜材料,用于包装、纺织和医疗等领域;油茶果壳富含木质素及茶皂素等天然活性物质,可制备油茶果壳基树脂用作做胶合材料并具有耐恶劣气候及阻燃等特性;油茶果壳经热压工艺制备刨花板,可用于家具及建筑等领域;油茶果壳作为增强相与塑料复合制备木塑复合材料,可用于园林和室内装潢等领域。本文综述了油茶果壳在上述领域的研究进展,并对油茶果壳生物基材料提出了展望。

耐热酚醛树脂基活性炭的制备及其超级电容器性能研究

活性炭因其大比表面积和低成本的优势,被广泛应用于超级电容器电极材料中。然而在活性炭的制备过程中,前驱体往往需要进行预炭化/氧化等处理以增强其热稳定性,这将会提高制备成本和工艺复杂性,不利于实际应用需求。为解决这一问题,本工作利用具有高度交联结构的耐热酚醛树脂为前驱体,通过一步活化法制备具有超高比表面及优异导电性的活性炭电极材料。最佳碱炭质量比为3∶1时所制备的活性炭比表面积高达2656m2·g^(-1)。在6 mol·L^(-1)KOH电解液中测试了活性炭电极的电容储能性能,1 A·g^(-1)时其比容量高达305.5F·g^(-1),在50A·g^(-1)的超大电流密度下电容保持率有63.8%,远高于目前商业活性炭水平。另外,其在高质量负载量下仍具有优异的容量、倍率、循环性能,表现出巨大的应用潜质。

酚醛树脂基活性炭球的合成及研究进展

酚醛树脂基活性炭球兼具球形活性炭及树脂基活性炭二者的优点,具有机械强度高、炭化收率高、吸附能力强、耐热性好、孔隙结构发达等特性。本文分别介绍了传统酚醛树脂基活性炭球和生物基酚醛树脂活性炭球的国内外研究进展及在吸附、超级电容器、催化剂载体等领域的应用现状,最后对酚醛树脂基活性炭球研究进行了展望。首先,应在降低成本和完善形貌等方面进一步探索;其次,以木质素、生物油等最大程度地代替苯酚制备生物基酚醛树脂活性炭球是今后研究的主要方向。

煤矸石-污泥基活性炭对苯酚的吸附

以煤矸石和污泥为原料、ZnCl_(2)为活化剂,制备了煤矸石-污泥基活性炭(CSAC)吸附剂,考察该吸附剂对溶液中苯酚的吸附去除效果。实验结果表明:在苯酚质量浓度为50 mg/L、CSAC投加量为7 g/L、初始pH为7~8、温度为(25±1)℃的条件下,当吸附时间为10 min时,CSAC对苯酚的吸附基本达到平衡,相应的吸附量为5.87 mg/g,苯酚去除率为83%;在其他条件相同、市售颗粒活性炭(AC)投加量为30 g/L的条件下,当吸附时间为120 min时,AC对苯酚的吸附达到平衡,相应的吸附量为1.05 mg/g,苯酚去除率仅63%。CSAC吸附苯酚的过程包含物理吸附和化学吸附,属于单层吸附,该过程是吸热的、熵增加的过程。表征结果显示:CSAC表面粗糙,由不定型的小颗粒紧密排列而成,比表面积和孔体积分别为258.74 m2/g和0.19 cm^(3)/g;CSAC中含有C=C、C=O、—OH、π-π基团等多种官能团,具有较好的吸附小分子有机物的能力。

二次喷雾造粒法制备石榴结构硅碳负极材料

为进一步优化多孔类核壳结构硅碳负极材料的制备方法,通过“两步喷雾造粒、一步碳化成型”法制备出了具有石榴结构状的锂离子电池硅碳负极材料。采用X射线衍射(X-ray diffraction,XRD)、扫描电子显微镜(scanning electron microsope,SEM)和热重分析(thermogravimetric analysis,TGA)等方法对材料的物理性质进行了表征。为提升复合材料的导电性与结构稳定性,提升其充放电性能,将碳纳米管(canbon nano tube,CNT)导电剂与鳞片石墨与复合材料进行了复合,得到了Si@Pore-C/CNT/G@C复合材料。该材料在0.1 C的电流密度下,在50次充放电循环后具有高达95.6%的容量保持率,并且在经过97次较长循环后仍具有82.8%的容量保持率。所提出的制备方式简单高效,具有量产的潜力,无需使用酸碱刻蚀或其他牺牲模板,是一种绿色、高效的制备方案。

改性酚醛树脂基活性炭对二氯甲烷的吸附

以酚醛树脂为前驱体经过炭化活化制得了酚醛树脂基活性炭(PFAC),分别采用不同金属离子及氨水、磷酸和磷酸氢二铵对PFAC进行改性,并采用BET、SEM、EDS、FTIR、XPS、拉曼光谱、NH_(3)-TPD等技术对活性炭进行表征,考察了其对二氯甲烷的吸附性能。结果表明:不同金属离子改性PFAC对二氯甲烷的吸附能力随表面总酸量和极化率的增大而增加,大小顺序为Fe^(3+)-PFAC>Cu^(2+)-PFAC>Mg^(2+)-PFAC>PFAC;氨水(N)、磷酸(P)和磷酸氢二铵(NP)改性PFAC对二氯甲烷的吸附能力大小顺序为NP-PFAC>N-PFAC>P-PFAC>PFAC,磷酸和磷酸氢二铵的改性有助于提高PFAC比表面积,氨水和磷酸氢二铵改性可使PFAC吸附位点增加;NP-PFAC具有较好的再生吸附能力。

Superior CO2 uptake on nitrogen doped carbonaceous adsorbents from commercial phenolic resin

In this study,N-doped porous carbons were produced with commercial phenolic resin as the raw material,urea as the nitrogen source and KOH as the activation agent.Different from conventional carbonization-nitriding-activation three-step method,a facile two-step process was explored to produce N-incorporated porous carbons.The as-obtained adsorbents hold superior CO2 uptake,i.e.5.01 and 7.47 mmol/g at 25℃and 0℃under 1 bar,respectively.The synergistic effects of N species on the surface and narrow micropores of the adsorbents decide their CO2 uptake under 25℃and atmospheric pressure.These phenolic resin-derived adsorbents also possess many extremely promising CO2 adsorption features like good recyclability,quick adsorption kinetics,modest heat of adsorption,great selectivity of CO2 over N2 and outstanding dynamic adsorption capacity.Cheap precursor,easy preparation strategy and excellent CO2 adsorption properties make these phenolic resin-derived N-doped carbonaceous adsorbents highly promising in CO2 capture.

不同离子交换树脂制备球形活性炭

本文以5种不同离子交换树脂进行了球形活性炭制备,分析了树脂氧化后的热解曲线,并对制备球形活性炭的表观形貌、比表面积、粒径情况进行分析。不同树脂制备的球形活性炭表面光滑度不同,放大倍数较高时除表面烧蚀的D001树脂能观察到蜂窝状的孔结构外,其余树脂均未有该现象;不同树脂炭孔结构分布不同,且除表面烧蚀的D001树脂炭外均具有较高的耐压强度;不同树脂炭的粒径与原料树脂相比均发生了一定的收缩。

酚醛基活性炭纤维孔结构及其电化学性能研究

利用水蒸汽活化法制备了酚醛基活性炭纤维(ACF-H2O),对其比表面积、孔结构与在LiClO4/PC(聚碳酸丙烯酯)有机电解液中的电容性能之间的关系进行了探讨.用N2(77K)吸附法测定活性炭纤维的孔结构和比表面积,用恒流充放电法和交流阻抗技术测量双电层电容器(EDLC)的电容量及内部阻抗.研究表明,在LiClO4/PC有机电解液中,ACF-H2O电极的可用孔径(d)应在0.7nm以上.随着活化时间的延长,ACF-H2O的孔容和比表面不断增大,但微孔(0.7nm<d<2.0nm)和中孔(d>2.0nm)率变化很小,活化过程中孔的延伸和拓宽同步进行,但过度活化则造成孔壁塌陷,孔容和比表面迅速下降.因此,除活化过度的样品外,电容量随比表面积呈线性增长,最高达到109.6F·g-1.但中孔和微孔的孔表面对电容的贡献不同,其单位面积电容分别为8.44μF·cm-2和4.29μF·cm-2,中孔具有更高的表面利用率.ACF-H2O电极的电容量、阻抗特性和孔结构密切相关.随着孔径的增大,时间常数减小,电解液离子更易于向孔内快速迁移,阻抗降低,电极具有更好的充放电倍率特性.因此,提高孔径和比表面积,减少超微孔(d<0.7nm),是提高EDLC能量密度和功率密度的重要途径.然而仅采用水蒸汽活化,只能在小中孔以下的孔径范围内进行调孔,ACF-H2O电极电容性能的提高受限.

沥青基球状活性炭的医用性能评价

表征了沥青基球状活性炭的基本结构参数 (如比表面积、孔容量、球形度、强度、重金属含量等 ) ,测定了其对血液中典型中、小毒性分子的吸附性能 (肌酐和VB1 2 )和溶血反应率 ,分析了以沥青基球状活性炭为吸附剂的人工炭肾的微粒释放量、热源和细菌含量 ,并进行临床试验。结果表明 :沥青基球状活性炭球形度好 ,强度高 ,具有良好的广谱吸附性能 ,对血液中典型的中、小毒性分子吸附能力强 ,重金属含量低 ,溶血率低 ,微粒释放量少 ,无热源、无菌 ,血液灌流临床试验效果满意 。