Non-Isothermal Kinetic Analysis of Thermal Decomposition of the Ca-Bentonite from Santai, China

The thermal decompositions of Ca-bentonites (CaB) from Santai ,Shichuan Province, China over the temperature rage of 30-1100℃ were investigated by simultaneous thermal analyzer. Non-isothermal Kinetic analysis were employed to study the thermal decomposition mechanism by using Netzsch Thermokinetics software. The dependence of the activation energy on conversion degree were evaluated by isoconversional methods. The probably mechanism and the corresponding kinetic parameters were determined by multivariate non-linear regression program.

Shenqi Fuzheng injection combined with GP chemotherapy in the treatment of advanced non-small cell lung cancer： a meta-analysis

Objective： To evaluate the clinical efficacy of Shenqi Fuzheng injection combined with gemcitabine plus cisplatin（GP） in the treatment of advanced non-small cell lung cancer （NSCLC）. Methods： we performed a systematicsearch in the electronic databases such as Cochrane Library, Pubmed, Embase, Chinese Journal Full-text Database,Chinese Biomedical Literature Database, Chinese Science and Technology Periodical Full-text Database andWanfang Database up to 30 January 2017. Randomized controlled trials （RCT） of Shenqi Fuzheng Injectioncombined with GP chemotherapy in the treatment of advanced NSCLC were searched, and all the RCTs wereconducted on methodological quality assessment. Data extraction and data analysis were according to standards ofCochrane systematic review. Results： Eight trials were included including a total of 701 patients. Meta-analysisresults： Shenqi Fuzheng injection combined with GP chemotherapy could significantly improve the functionalstatus of patients with NSCLC （OR = 3.44, 95% CI [2.26, 5.25], P 〈 0.0001） and clinical treatment efficacy （OR =（OR = 0.31, 95%CI [0.20, 0.47], P 〈 0.0001. The rate of leukopenia （OR = .31, 95%CI [0.20,0.47], P 〈 0.0001）,thrombocytopenia （OR = 0.58, 95%CI [0.37, 0.91], P = 0.020）, hemoglobin decline （（OR = 0.31, 95%CI [0.16,0.59], P = 0.0004） and incidence of gastrointestinal reactions （OR = 0.58,P 〈 0.05） could be reduced. Conclusion：Shenqi Fuzheng injection combined with GP chemotherapy in the treatment of advanced NSCLC obtainedsignificantly clinical efficacy. The quality of the literature incorporated is low, the conclusion requires high-qualityresearch to further prove.

Non-Isothermal Degradation and Thermodynamic Properties of Pine Sawdust

The study of non-isothermal kinetics analyzed the reactivity of pine sawdust, while the thermodynamic properties analyzed energy consumed and released from the pine sawdust. The kinetic parameters were determined by analyzing mass loss of pine sawdust components by using Thermogravimeric analyzer. The cellulose has the highest conversion rate of 9.5%/min at 610 K compared to hemicellulose and lignin, which are 5%/min at 600 K and 2%/min at 800 K, respectively. The activation Energy for cellulose, hemicellulose and lignin was 457.644, 259.876, and 89.950 kJ/mol, respectively. The thermodynamic properties included the change of Gibbs free energy for cellulose and hemicellulose, which were -214.440 and -30.825 kJ/mol respectively, their degradation was spontaneous in forward direction, while change of Gibbs free energy for lignin was 207.507 kJ/mol, which is non-spontaneous reaction. The positive value of change of entropies for the active complex compounds formed from hemicellulose and cellulose is less stable, while the active complex compounds of lignin are characterized by a much higher degree of arrangement since its change of entropy is negative. The kinetic and thermodynamic properties show that pine sawdust is a good candidate for production of char since it is easier to remove hemicellulose through thermal process.

Combustion Property and Kinetic Modeling of Pulverized Coal Based on Non-isothermal Thermogravimetric Analysis

Non-isothermal combustion kinetics of two kinds of low volatile pulverized coals （HL coal and RU coal） were investigated by thermogravimetrie analysis. The results show that the combustibility of HL coal was better than that of RU coal, and with increasing heating rate, ignition and burnout characteristics of pulverized coal were improved. The volume model （VM）, the random pore model （RPM）, and the new model （NEWM） in which the whole combustion process is considered to be the overlapping process of volatile combustion and coal char combustion, were used to fit with the experimental data. The comparison of these three fitted results indicated that the combustion process of coal could be simulated by the NEWM with highest precision. When calculated by the NEWM, the activation energies of volatile combustion and coal char combustion are 130.5 and 95.7 kJ · mol^-1 for HL coal, respectively, while they are 114.5 and 147.6 kJ ·mol^-1 for RU coal, respectively.

PROGRESS IN ION BEAM ANALYSIS AT FUDAN UNIVERSITY

Progres in ion beam analysis at Fudan University in the recent years is briefly reviewed. Presented as examples of the research activities performed in this field are the following projects: (1) Nuclear potential resonance scattering of 6.25 MeV and 4.25 MeV helium ions for simultaneous compositional analysis of carbon and oxygen in a Mylar, a SnInO, and some other film samples: (2) Determination of stoichiometry of a high-temperature superconducting Y-Ba-Cu-O sample by backscattering of 8.8 MeV helium ions; (3) Backscattering and channeling analysis of multilayered structures periodically consisting of layers of pure Si and alternate layers of Ge and Si, grown on (100) Si substrates by molecular beam epitaxy: (4) Studies of surface structure of Al(100) by the use of MeV ions backscattering and channeling surface peak: and (5) MeV ion microbeam analysis and the use of PIXE method in DNA study. etc.

黄铁矿在CO_(2)气氛下非等温氧化转化及动力学分析

针对煤中常见含铁矿物黄铁矿在富氧燃烧典型气氛下转化特性,通过同步热分析结合烟气分析研究了黄铁矿在CO_(2)气氛下的转化行为.结果发现,黄铁矿在CO_(2)气氛下主要经历5个失重阶段且均为吸热过程,首先是黄铁矿颗粒表面硫脱除的起始热解段(相界面反应,n=1/2),活化能低于其在N_(2)气氛下近30 kJ/mol,为220.27 kJ/mol,随后裂解成磁黄铁矿(三维扩散,n=1/2)活化能与其在N_(2)(177.27 kJ/mol)下接近为178.1 kJ/mol;温度高于690℃,随着升温磁黄铁矿缓慢失硫,CO_(2)逐渐参与磁黄铁矿转化且释放SO_(2)和CO;820~1150℃经历双峰失重峰阶段,820~1020℃,氧化气体产物SO_(2)大量生成且在约1000℃达到体积浓度峰值;最后1020~1150℃,坩埚中残留物大量与CO_(2)持续氧化反应失重形成SO_(2)和CO,坩埚中形成复杂物相体系,铁硫化物和铁氧化物共存(或共融).CO_(2)参与黄铁矿产物转化失重阶段活化能分别为180.94 kJ/mol、229.69 kJ/mol和243.46 kJ/mol,动力学机制均为成核与生长(n=1).

DL-2-萘普生热分解过程和非等温热分解动力学研究

用热重-差热联用分析（DTA-TGA）技术和差动扫描（DSC）技术研究了DL-2-萘普生在空气中的热分解过程和非等温热分解机理及动力学。DTA-TGA分析表明DL-2-萘普生在（（250.72~296.87）±4.88）℃之间发生热分解反应,结合DSC分析表明DL-2-萘普生的熔点为（158.16±0.6）℃,熔融热为（140.57±2.10）J·g-1。运用Achar法和Coats-Redfern法对非等温动力学数据进行分析,得到热分解反应的机理函数和动力学参数,其热分解反应为二级反应机理,表观活化能为E=201.558 kJ·mol-1,指前因子A=7.52×1024 s-1。

3,3-二叠氮甲基氧丁环与3-叠氮甲基-3-甲基氧丁环均聚物的嵌段共聚物热分解机理及非等温裂解动力学分析

3,3-二叠氮甲基氧丁环与3-叠氮甲基-3-甲基氧丁环均聚物的嵌段共聚物(BAMO-AM-MO)是一种含能黏合剂,为了解其受热分解机理及分解动力学情况,采用DSC法、TG-DTG法、固相原位池-FTIR联用技术和DSC-TG-MS联用技术探讨了BAMO-AMMO的热分解过程及机理。研究结果表明,BAMO-AMMO受热分解主阶段为叠氮基团分解,释放出N2,裂解过程中形成亚胺中间体,并放出大量的热,放热量为1 663 J/g.同时,由于叠氮基团分解引起其他基团的重排,而引起共聚物的深度分解。采用程序升温(升温速率为2.5、5、10、20℃/min)的DSC数据,根据非等温动力学方程Kissinger法、Ozawa法和Coats-Redfern法计算了BAMO-AMMO受热分解主阶段的非等温反应动力学参数。获得BAMO-AMMO分解主阶段的表观活化能为164.2 kJ/mol,指前因子为1014.14 s-1.计算结果表明,BAMO-AMMO受热分解具有局部化学反应特征,其分解动力学服从Avrami-Erofeyev成核与生长(n=1.5)过程。受热分解非等温动力学方程可表示为dα/dt=2.071×1014 exp(-1.975×104/T)(1-α)[-ln(1-α)1/3].

注塑级聚乳酸热分解动力学分析

目的研究注塑级聚乳酸材料的热分解动力学,准确理解注塑级聚乳酸的耐热稳定性,为开发耐高温阻燃注塑级聚乳酸(PLA)材料提供理论依据。方法通过非等温热重分析法,采用5、10、15、20、25℃/min的升温速率,研究注塑级PLA在氮气气氛中的热分解行为,利用1种微分法和3种积分法进行详细的动力学计算。比较相关系数及标准偏差,选取KAS等温积分法,以相对偏差Ai=|1–αc/αe|为目标函数,利用16种热分解动力学机理模拟计算注塑级PLA热分解最合适的反应机理。结果得到了注塑级PLA热分解所需的活化能和指前因子,其中Kissinger、Madhusudanan-Krishnan-Ninan(MKN)、Kissinger-Akahira-Sunose(KAS)和Flynn-Wall-Ozawa(FWO)法计算所得注塑级PLA活化能分别为177.01、174.43、173.01和173.28 kJ/mol。指前因子分别为25.84、26.69~33.75、25.83~32.89和26.38~32.94。结论确定了随机成核和随后生长反应机理(A1/4),ln(β/T2)=ln[4.75×10^(9)/–ln(1–α)]–2.08×10^(4)/T是描述注塑级PLA热分解最合适的反应机理。

原位增容PA6/PE-HD共混物的非等温结晶动力学研究

利用差示扫描量热仪研究了原位增容的聚酰胺6/高密度聚乙烯(PA6/PE-HD)共混物的非等温结晶过程,用经Jeziorny修正的Avrami方程和Mo法对其非等温结晶动力学进行了研究,计算并得到非等温结晶动力学参数。结果表明,该方程和方法适合于处理纯PA和PA6/PE-HD共混物的非等温结晶过程;在PA6/PE-HD共混物非等温结晶过程中,在其初期结晶阶段可能同时包含了均相成核和异相成核,在二次结晶阶段结晶生长可能是一维生长,并且PE-HD的加入,起到异相成核的作用,促进了晶核的生长。此外,还利用Vyazovkin的方法求出PA6/PE-HD共混物结晶活化能与温度之间的关系。

5-硝氨基四唑高氮盐的合成及性能

合成了5-硝氨基四唑乙二胺盐、肼盐及碳酰肼盐3种新型高氮含能盐,用缓慢蒸发溶剂法培养了5-硝氨基四唑碳酰肼盐的单晶,用元素分析、红外光谱、DSC、TG-DTG和X射线单晶衍射等方法对该化合物进行了表征。结果表明,该晶体属于单斜晶系,空间群为Pn,晶胞参数a=0.373 89(1)nm,b=1.239 6(5)nm,c=0.869 9(4)nm,β=92.212(7)°,V=0.402 9 nm3;ρ=1.815 g/cm3;Z=2;F(000)=228,L=0.160 mm,R1=0.025 3,wR2=0.055 0。热分析和感度测试结果表明,在10 K/min的升温速率下,5-硝氨基四唑乙二胺盐的DSC曲线仅有一个放热峰,而5-硝氨基肼盐、碳酰肼盐的DSC曲线都是由一个吸热峰和一个放热峰组成;无残渣剩余;3种盐的机械感度较高,火焰感度较低。

非等温热重分析研究煤焦气化动力学

使用等温法和非等温法热重分析研究了神府煤焦气化反应动力学.在非等温法中,Doyle和Coats-Redfern近似函数都可以模拟煤焦气化反应过程,两种函数在不同的升温速率下得到了与等温法相近的E值.对比两个函数拟合实验数据的相关系数,确定在非等温热重分析中使用Coats-Redfern函数在15℃/m in的升温速率下求取煤焦气化反应动力学参数是一种既简便又准确的方法.

一种新的热分析动力学处理方法

用一种新的方法对一水草酸钙(CaC2O4·H2O)脱水反应的热分析动力学三因子,即活化能Ea、指前因子A和反应机理函数f(α)进行了求取.此方法可分为三步:(1)用迭代的方法求取Ea值;(2)用Popescu的方法求取反应的f(α);(3)由以上两步所得的结果求取指前因子A.此方法有两大优点:对动力学参数Ea和f(α)分别进行求取,从而使f(α)求取的准确性不因Ea值求取是否存在误差而受影响;在f(α)的求取中没有引入任何积分误差,从而提高了计算结果的准确性.

硫酸钙的还原热分解特性研究

为了有效利用工业副产石膏,降低硫酸钙分解能耗,文章对硫酸钙的还原热解特性进行了研究。采用Gibbs-Helmholtz方程、Van't Hoff方程、Kirchhoff方程分别对硫酸钙在不同还原剂中的分解热力学进行计算,结果表明加入还原剂可降低硫酸钙的分解温度。采用整体优化的多升温速率(2.5,5,7.5,10,15K/min)等转化率迭代法对硫酸钙与碳的反应进行动力学计算,求得反应活化能为259.92kJ/mol,反应机理为相边界反应,机理函数为α2/3,指前因子为3.2452×109s-1。

氯氧镁水泥的制备及其热分解机理

用XRD测试合成氯氧镁水泥试样的组成,利用DSC、TG测试手段研究了它的热分解过程,应用Kinssinger法和Dolye-Ozawa法处理了不同升温速率下氯氧镁水泥的DSC曲线,得到的各阶段的平均表观活化能分别为125.5 kJ/mol,113.61 kJ/mol,116.26 kJ/mol;反应级数分别为2.11,2.04,0.98。推断了氯氧镁水泥的阻燃机理,研究表明,氯氧镁水泥可以通过气相、凝聚相阻燃及中断热交换阻燃机理来实现对聚合物的阻燃作用,是一种新型的无机阻燃剂。

系阻燃钛合金的非等温氧化行为及阻燃性能预测

采用TGA/DSC实验方法,结合XRD,SEM和EDS分析,系统研究Ti-V,Ti-V-Cr合金的非等温氧化行为及氧化产物的微观结构,并探讨V和Cr元素对Ti-V-Cr阻燃钛合金抗非等温氧化性的影响机制。结果表明:从室温至1723K温度区间内,随着V元素含量的增加,Ti-V合金的抗非等温氧化性显著降低,氧化膜厚度从168μm增加至370μm,Ti-35V合金氧化膜厚度约为Ti-25V的1.45倍;Ti-V-Cr合金的抗非等温氧化性逐渐提高且差异较小,氧化膜厚度从110μm减小至85μm,Ti-35V-15Cr合金的氧化膜厚度比Ti-25V-15Cr降低约15.5%。Ti-V-Cr阻燃钛合金的抗非等温氧化性显著高于Ti-V合金,主要因为非等温氧化过程形成的液态相V_2O_5极大地释放了氧化膜的内应力,提高了氧化膜与合金基体的结合性,并与Cr_2O_3,TiO_2共同阻止了O向合金基体的大量扩散。非等温氧化增重曲线及氧化膜厚度作为特征参数定量描述了Ti-V-Cr阻燃钛合金的抗非等温氧化性,与摩擦着火实验结果相一致,从而预测了合金的阻燃性能。

模锻压机超低速运行动态性能分析

在考虑非线性摩擦的基础上,从参数分析的角度对模锻压机动态特性进行研究,并结合实际锻压机系统的仿真实验研究各种因素对超低速动态性能的影响规律。研究结果表明:非线性摩擦力的负阻尼特性是导致系统速度不稳定的主要原因,减小摩擦的负阻尼或增大负载阻尼系数,可增大系统稳定性;减小最大静摩擦力、质量、初始容积或增大油缸作用面积、油液弹性模量,可以减小响应延时。

微型流化床与热重测定煤焦非等温气化反应动力学对比

利用微型流化床反应分析仪(MFBRA)和热重分析仪(TGA)比较煤焦与CO2的非等温气化反应特性,并利用单一升温速率法和组合升温速率法计算反应动力学数据。结果表明:升温速率对半焦非等温气化过程有重要影响,随着升温速率的增大,起始反应温度和最大反应速率对应的气化温度增加,同一气化温度下的碳转化率降低,而且利用单一升温速率法求取气化反应的活化能逐渐减小。与TGA相比,同一升温速率下,MFBRA中半焦气化反应的起始反应温度和最大反应速率对应的反应温度明显较小,而且升温速率越大差异越显著。无论是单一升温速率法(升温速率≥5℃·min-1)还是组合升温速率法,TGA测得的动力学数据均明显小于MFBRA测得的动力学数据。高升温速率下(升温速率≥5℃·min-1)半焦在TGA和MFBRA中非等温气化行为和动力学数据的差异很可能与MFBRA内较好的热量传递和受扩散的抑制作用较小有关。

非等温热重分析研究碳气化动力学

利用Labsys同步热分析仪以非等温热重分析研究了碳气化反应动力学,考察了升温速率对碳气化反应的影响.在非等温热重分析中,Doyle和Gorbatchev近似函数都可以模拟碳气化反应过程.通过对比这两个函数拟合实验数据的相关系数,确定在使用非等温热重分析研究碳气化反应动力学时,使用Gorbatchev函数是求取反应动力学参数的较好方法.结果表明:活化能和指前因子都随着升温速率的增加而减小.活化能和指前因子之间有着较好的线性关系,碳气化反应过程中存在着动力学补偿效应.

六氨氯化镁热解过程及其非等温动力学

利用热重(TG)分析技术对六氨氯化镁的热分解过程及动力学进行了研究,考察了六氨氯化镁在4、7、10、13、16K·min-1线性升温速率和空气气氛下热分解机理,六氨氯化镁热解过程分为3个阶段。提出了一种整体优化的多升温速率迭代的等转化率求取活化能方法,采用该方法,得到六氨氯化镁热解3个阶段的活化能分别为51.38、64.70、73.55kJ·mol-1。采用整体优化的多升温速率等温法确立了六氨氯化镁热解3个阶段的热解机理函数与指前因子:第1步反应的热解机理属于固体相边界反应机理(n=1/4),指前因子为3.281×105s-1;第2步反应的热解机理属成核与生长机理(n=1.8),指前因子为5.624×106s-1;第3步反应属化学反应机理(1.5级反应),指前因子为5.862×105s-1。