煤粉的增压富氧燃烧特性及煤灰矿物演变

为了更好地了解煤粉在增压富氧条件下的燃烧过程,利用加压热天平(PTGA)结合X射线衍射仪(XRD),研究了增压富氧燃烧条件下压力对煤粉燃烧特性及煤中矿物演变的影响。研究表明,随着压力的升高,煤粉常压时的非均相着火逐渐转变为均相着火,当压力升高到3 MPa开始向非均相着火过渡,并在5 MPa时完全转变成非均相着火。由于煤粉着火机理的转变,综合燃烧特性指数S随着压力的增加先升高后降低。不同的着火机理下,煤粉的燃烧温度也会有所差别。常压时非均相着火较高的燃烧温度使得反应生成了莫来石等矿物,而1 MPa时均相着火较低的燃烧温度则使得煤灰中出现了伊利石等矿物。压力继续升高,均相着火开始向非均相着火过渡,燃烧温度逐步升高,伊利石逐渐转变为莫来石。     

铜基催化剂上甲烷催化燃烧反应动力学特性研究

采用固定床微分反应器,在常压、450~500℃、甲烷体积分数10%~35%条件下,进行铜基催化剂上甲烷催化燃烧动力学特性研究。研究表明,甲烷分压对反应速率影响显著,而氧气分压的影响可以忽略。采用最小二乘法进行动力学模型参数估计,建立的反应动力学模型为-rCH4=1.61×107×e-108 000/RT×pCH40.5。检验结果表明,所建模型与实验数据良好相容,是适宜和可信的。根据实验结果推断甲烷催化燃烧分两步进行,首先氧气快速与铜基催化剂上活性空位点反应,形成吸附氧气分子;随后吸附氧气分子和甲烷分子反应,生成二氧化碳和水。     

增压O_2/CO_2气氛下煤燃烧特性实验研究

增压O2/CO2燃烧是一种可高效分离回收CO2的新兴燃烧技术,其燃烧机理与常压空气、常压O2/CO2燃烧存在较大差异。在加压热重分析仪上研究了增压条件下总压、氧浓度、气氛及粒径等反应参数对美国烟煤和淮北无烟煤燃烧特性的影响,确定了煤的着火温度,并对其进行燃烧动力学分析。结果表明,增压O2/CO2气氛下,随着压力或氧浓度的增加,DTG曲线向低温区移动,煤样整体燃烧速率加快。压力提升、氧浓度增加及煤粉细化均可改善O2/CO2气氛下煤样的着火特性。常压O2/CO2气氛下煤粉燃烧基本属于一级反应;增压O2/CO2气氛下,低温区属于0.5级反应,而高温区属于1.5级反应。     

O2/CO2气氛下CO2和H2O气化反应对煤及煤焦燃烧特性的影响

利用热天平对比研究了大同煤及煤焦在O₂/N₂、O₂/CO₂和O₂/H₂O/CO₂中的燃烧行为,探讨CO₂和H₂O气化反应对其富氧燃烧特性的影响。结果表明,在5%氧气浓度下,煤粉在O₂/N₂、O₂/CO₂和O₂/H₂O/CO₂中的燃烧速率按顺序依次降低。氧气浓度降低到2%,由于CO₂和H₂O气化反应的作用,煤粉在高温区的整体反应速率按顺序依次增大。当氧气浓度为5%时,煤焦在O₂/CO₂中的燃烧速率要低于O₂/N₂中的燃烧速率,但燃烧反应推迟后气化反应的参与使得煤焦在O₂/H₂O/CO₂中的整体反应速率显著升高。当氧气浓度降低到2%后,随着温度的升高,在CO₂气化反应的作用下,煤焦在O₂/CO₂中的整体反应速率逐渐高于O₂/N₂中的燃烧速率。在O₂/H₂O/CO₂中,由于H₂O在共气化中起主要作用,煤焦在O₂/H₂O/CO₂高温区的整体反应速率进一步升高。动力学分析表明,在5%氧浓度时,煤焦在O₂/N₂、O₂/CO₂和O₂/H₂O/CO₂中的表观活化能依次升高。随着氧气浓度的降低,在不同反应气氛中的表观活化能均有所下降。     

低阶煤半焦利用热重在O_2/CO_2、O_2/N_2和O_2/Ar气氛下燃烧特性研究（英文）

利用热重研究了两种中国西北典型低阶煤半焦的燃烧特性。探究了不同气氛(O_2/CO_2、O_2/N_2和O_2/Ar)和不同氧气浓度对其燃烧特性的影响。实验结果表明,无论是反应气氛还是氧气浓度都会对低阶煤半焦的燃烧产生影响。相比于N_2和Ar,CO_2明显有利于燃烧反应进行:当反应气氛由O_2/CO_2变为O_2/Ar时,两种不同低阶煤半焦的燃尽温度分别升高了63.7和68.8℃;而当反应气氛由O_2/CO_2变为O_2/N_2时,两种不同低阶煤半焦的燃尽温度分别升高了135.9和129.6℃。在研究范围内,氧气浓度的提高也能明显提高半焦的燃烧性能。与此同时,半焦燃烧特性的动力学分析表明,随着氧气浓度提高,两种半焦燃烧反应的表观活化能E和指前因子A均呈增大趋势。通过对E和A两者关系的分析结果表明,半焦富氧燃烧的活化能和指前因子存在动力学补偿效应。     

反胶团萃取铅的动力学机理研究

利用恒界面池研究了二壬基萘磺酸(DNNSA)反胶团溶液萃取模拟电池废水中铅离子的动力学。考察了搅拌转速、DNNSA、初始铅离子浓度以及温度对萃取速率的影响,得到了DNNSA反胶团萃取废水中铅离子的动力学方程并对萃取机理进行了探讨。结果表明,当搅拌速率在200r/min时出现与搅拌强度无关的动力学"坪区",萃取过程为化学反应控制。在动力学"坪区",铅离子萃取速率随着萃取剂DNNSA浓度和水相铅离子浓度增加而增加,温度升高萃取速率加快,萃取反应活化能为35.11k J/mol。     

低阶煤半焦利用热重在O2/CO2、O2/N2和O2/Ar气氛下燃烧特性研究

利用热重研究了两种中国西北典型低阶煤半焦的燃烧特性。探究了不同气氛（O₂/CO₂、O₂/N₂和O₂/Ar）和不同氧气浓度对其燃烧特性的影响。实验结果表明,无论是反应气氛还是氧气浓度都会对低阶煤半焦的燃烧产生影响。相比于N₂和Ar,CO₂明显有利于燃烧反应进行：当反应气氛由O₂/CO₂变为O₂/Ar时,两种不同低阶煤半焦的燃尽温度分别升高了63.7和68.8℃;而当反应气氛由O₂/CO₂变为O₂/N₂时,两种不同低阶煤半焦的燃尽温度分别升高了135.9和129.6℃。在研究范围内,氧气浓度的提高也能明显提高半焦的燃烧性能。与此同时,半焦燃烧特性的动力学分析表明,随着氧气浓度提高,两种半焦燃烧反应的表观活化能E和指前因子A均呈增大趋势。通过对E和A两者关系的分析结果表明,半焦富氧燃烧的活化能和指前因子存在动力学补偿效应。     

钛酸锌高温煤气脱硫剂再生行为的研究

在热天平装置上研究了再生反应温度、反应气体中氧气体积分数、脱硫剂颗粒粒径对钛酸锌高温煤气脱硫剂再生行为的影响。实验结果表明，较高的反应温度和氧气体积分数，较小的颗粒粒径有利于提高脱硫剂的再生反应速率。由于二次反应的影响，脱硫剂再生过程中有硫酸盐生成，提高反应温度或降低反应气体的氧气体积分数可以减少硫酸盐的生成。利用收缩核模型对其动力学行为进行了分析，结果表明，脱硫剂的再生过程存在动力学控制步骤的转移。脱硫剂再生转化率较低（<65%）时，再生过程主要受化学反应控制；再生转化率较高（>75%）时，再生过程主要受颗粒内扩散控制。表观化学反应速率常数的指前因子为8.01×10－2 m/s，活化能为19.11 kJ/mol；有效扩散系数的指前因子为3.12×10－4 m2/s，扩散活化能为48.84 kJ/mol。     

二苯基二氯硅烷与双酚-A的缩聚反应动力学

研究了二苯基二氯硅烷与双酚-A在等克分子比条件下的缩聚反应动力学。采用熔融缩聚时反应速率规律性复杂,结果无法处理;而用萘、二苯醚、苯乙酮等溶剂稀释至一定程度后,前期反应动力学呈现二级反应规律。当温度相同时,溶剂极性越大,反应速率越快;在一定温度范围内反应速率常数的对数与绝对温度的倒数标绘呈线性关系,获得在萘、二苯醚、苯乙酮中缩聚反应的活化能分别为:17.1千卡/克分子,24.8千卡/克分子,10.3千卡/克分子。Lewis碱及其盐对此反应有显著的催化效应。验证了缩聚反应过程中体系极性改变时,反应速率即发生对应的变化,阐明了熔融缩聚反应速率不稳定的原因。提出了反应系按S_N2机理进行。     

以壳聚糖为模板的对苯二酚氧化聚合反应表观动力学研究

以壳聚糖为模板在酸性溶液中实现了对苯二酚的氧化聚合.该反应必须在氧气存在的条件下才能进行.动力学研究表明该氧化聚合反应是以选取机理进行的模板聚合反应.当壳聚糖残基与对苯二酚的摩尔比小于0.8时,反应速度与壳聚糖浓度成正比.当壳聚糖残基与对苯二酚的摩尔比大于0.8时,反应速度不再随壳聚糖浓度提高而提高.反应对对苯二酚而言是一个一级反应.反应的活化能为71.6kJ/mol.     

旋流煤粉燃烧的一维综合数值模拟

发展了综合考虑气－固两相旋流流动，气相燃烧，颗粒相变与燃烧及两相辐射传热的旋流煤粉燃烧－维数学模型，给出了气－固两相能量方程中颗粒相就源项的计算表达式，应用这一模型对涡旋燃烧炉环形通道内多组工况的旋流气体燃烧和煤粉燃烧进行了数值模拟，计算得到的炉内温度分布和燃烧效率与实验数据基本相符，表明本文建立的模型可用于旋流煤粉燃烧的一维综合数值模拟。     

Comparison of pulverized coal combustion in air and in O2/CO2 mixtures by thermo-gravimetric analysis

Thermo-gravimetric technique was used to study the combustion characteristics of pulverized coal in different O₂/CO₂ environments. The effects of combustion environment, oxygen concentration, particle size and heating rate were considered and the differences of pulverized coal pyrolysis, combustion and gaseous compounds release under two environments were analyzed. Results show that the coal pyrolysis in CO₂ environment can be divided into three stages: moisture release, devolatilization and char gasification by CO₂ in higher temperature zone. In the lower temperature zone, the mass loss rate of coal pyrolysis in CO₂ environment is lower than that in N₂ environment. The burning process of pulverized coal in O₂/CO₂ environment is delayed compared with that in O₂/N₂ environment for equivalent oxygen concentrations. With the oxygen concentration increase or the coal particle size decrease, the burning rate of coal increases and burnout time is shortened. As the heating rate increases, coal particles are faster heated in a short period of time and burnt in a higher temperature region, but the increase in heating rate has almost no obvious effect on the combustion mechanism of pulverized coal. During the programmed heating process, species in flue gas including H₂O, CO₂, CO, CH₄, SO₂ and NO were determined and analyzed using the Fourier-transform infrared (FTIR) spectrometer. Compared with pulverized coal combustion in O₂/N₂ environment, much more CO is produced in O₂/CO₂ coal combustion process, but the releases of SO₂ and NO are less than those released in O₂/N₂ environment. The present results might have important implications for understanding the intrinsic mechanics of pulverized coal combustion in O₂/CO₂ environment.     

燃煤固硫及催化燃烧一体化添加剂的催化作用机理研究

用热重法研究了燃煤固硫及催化燃烧一体化添加剂对峰峰烟煤的催化燃烧和催化固硫作用，采用非等温燃烧反应模型和粒子模型，计算了加入一体化添加剂前后煤的燃烧反应动力学和固硫反应动力学参数，对一体化添加剂的催化作用机理进行了分析。结果表明，一体化添加剂中金属催化组分Fe2O3对煤的燃烧和固硫组分CaO的固硫均起到了较好的催化促进作用。一体化添加剂的加入可提高煤的燃烧反应速率，外加金属离子通过电荷迁移使碳表面的棱、角、缺陷等活性部位增加，加快了氧气的吸附速度，使反应活化能和频率因子降低。在燃烧固硫反应，一体化添加剂中金属助剂Fe2O3催化了SO2转变为SO3的过程，使固硫组分CaO的硫酸盐化反应表面化学反应速度常数k和有效扩散系数D增大，在固硫反应的产物层扩散控制阶段，Fe2O3的存在使得CaO晶粒团之间相互接触黏连的几率减小，减轻了固硫产物CaSO4的团聚，弱化了扩散作用的影响，减轻了CaO固硫反应的孔窒息效应。     

加压下煤的着火特性的研究 Ⅰ.着火特性的影响因素

采用带程序升温控制的、可在加压下测定煤着火特性的装置,在程序升温速度(7.5℃/min)和加压条件下,测定了影响煤和煤焦着火特性(着火温度与燃烧时间)的各种因素,这些因素包括煤的粒度、试样质量、空气流量、系统压力和氧分压等。试验表明,这些因素的影响与煤中挥发份有一定的关系,着火温度和燃烧时间随总压或氧分压增加而下降。     

煤燃烧中的汞转化模型和数值模拟

煤燃烧中汞高温下以单质形式存在，在烟道里随着温度降低，单质汞部分转化为二价汞，并再有部分汞吸附在灰渣中而被除尘设备收集，减少了环境的汞污染。针对煤燃烧汞的转化过程，用动力学模型和吸附模型结合来描述汞的转化机理，并用数值模拟方法研究了煤中氯的质量分数、烟气降温速率、烟气停留时间等因素的影响。结果表明，煤中氯的质量分数为0.08×10－6以上，烟气停留6s以上时，可以使汞的吸附率达到40％以上。对汞转化模型，用一组580MJ/h燃烧系统150℃烟道温度数据进行了验证，结果证实试验数据与计算数据能较好相符，模型具有一定的可靠性。     

The kinetics of tobacco pyrolysis

When tobacco is pyrolysed under non-isothermal flow conditions in an inert atmosphere, variation of the inert gas or its space velocity has only a minor effect on the profiles of formation rate versus temperature for seven product gases. Thus, mass transfer processes between the tobacco surface and the gas phase are very rapid, and the products are formed at an overall rate which is determined entirely by that of the chemical reactions.The effect of radical chain inhibitors (nitrogen oxides) on the pyrolysis is complex because of the resultant oxidation. Nevertheless, no evidence was found for the occurrence of radical chain reactions in the gas phase. A small proportion (less than 10%) of all the gases monitored are formed by homogeneous decomposition of volatile and semi-volatile intermediate products, in the furnace used.At temperatures above about 600°C the reduction of carbon dioxide to carbon monoxide by the carbonaceous tobacco residue becomes increasingly important. However, when tobacco is pyrolysed in an inert atmosphere, only a small amount of carbon dioxide is produced above 600°C and consequently its reduction to carbon monoxide contributes only a small proportion to the total carbon monoxide formed above that temperature. The rate of the tobacco/carbon dioxide reaction is controlled by chemical kinetic rather than mass transfer effects. Carbon monoxide reacts with tobacco to a small extent.When the tobacco is pyrolysed in an atmosphere containing oxygen (9–21% v/v), some oxidation occurs at 200°C. At 250°C the combustion rate is controlled jointly by both kinetic and mass transfer processes, but mass transfer of oxygen in the gas phase becomes increasingly important as the temperature is increased, and it is dominant above 400°C. About 8% of the total carbon monoxide formed by combustion is lost by its further oxidation.The results imply that inside the combustion coal of a burning cigarette the actual reactions occurring are of secondary importance, the rate of supply of oxygen being the dominant factor in determining the combustion rate and heat generation. In contrast, in the region immediately behind the coal, where a large proportion of the products which enter mainstream smoke are formed by thermal decomposition of tobacco constituents, the chemistry of the tobacco substrate is critical, since the decomposition kinetics are controlled by chemical rather than mass transfer effects. tobacco substrate is critical. In addition, the heat release or absorption due to the pyrolytic reactions occurring behind the coal will depend on the chemical composition of the substrate. Thus, together with the differing thermal properties of the tobacco, the temperature gradient behind the coal should depend on the nature of the tobacco.     

Thermal analysis of Beypazari lignite

Beypazari lignite was investigated by differential scanning calorimetry (DSC), thermogravimetry (TG), high pressure thermogravimetry (HPTG) and combustion cell experiments. All the experiments were conducted at non-isothermal heating conditions with a heating rate of 10°C min^?1, in the temperature range of 20–700°C. DSC-TG data were analysed using an Arrhenius-type reaction model assuming a first-order reaction. For the HPTG data the Coats and Redfern equation was used for kinetic analysis. In the combustion cell experiments the Fassihi and Brigham approach was used in order to calculate kinetic data. Finally a comparison is made between the kinetic results.     

聚氯乙烯燃烧特性及HCl的生成机理

采用热重法对聚氯乙烯（ＰＶＣ）的燃烧过程进行了研究,探讨阳聚氯乙烯燃烧科技司,并由它们的微分热重曲线计算出的反应动力学参数及影响反应常数的因素进行了研究。同时,考察了恒速升温和快速升温过程ＨＣＩ的生成特性。结果表明,ＰＶＣ的燃烧机理是由三个过程决定的,可用三个一级反应表示。ＰＶＣ的燃烧过程的第一阶段为脱氯阶段。第二阶段的活化能和指前因子明显低于第一和一阶段。此阶段为挥发分释放阶段。升温速率的增加导