Gasification kinetic modelling of Victorian brown coal chars and validity for entrained flow gasification in CO_(2)

The gasification kinetic modelling of two Victorian brown coal(Yallourn and Maddingley)chars and the validity for entrained flow gasification were investigated in this study.The study was conducted in a thermogravimetric analyzer(TGA)at 750–1100℃,30%–90%CO_(2)concentration using different char particle sizes within 20–106 mm.It was found that random pore model and modified volumetric model are applicable for TGA results,but volumetric model and grain model are not.The effect of particle size under106 mm on gasification rate is very limited.Activation energies of Maddingley char and Yallourn char in CO_(2)gasification are 219–220 and 197–208 k J/mol,respectively.The pre-exponential factors are in the same order of magnitude,and they increased as particle size decreased.A mathematical model was developed to predict carbon conversion over time for entrained flow gasification of Victorian brown coal chars at 1000–1400℃.

Experiment research on two-stage dry-fed entrained flow coal gasifier

The process flow and the main devices of a new two-stage dry-fed coal gasification pilot plant with a throughout of 36 t/d are introduced in this paper. For comparison with the traditional one-stage gasifiers, the influences of the coal feed ratio between two stages on the performance of the gasifier are detailedly studied by a series of experiments. The results reveal that the two-stage gasification decreases the temperature of the syngas at the outlet of the gasifier, simplifies the gasification process, and reduces the size of the syngas cooler. Moreover, the cold gas efficiency of the gasifier can be improved by using the two-stage gasification. In our experiments, the efficiency is about 3%-6% higher than the existing one-stage gasifiers.

Employment of Two-Stage Oxygen Feeding to Control Temperature in a Downdraft Entrained-Flow Coal Gasifier

The traditional practice of employing a two-stage coal-fed gasification process is to feed all of the oxygen to provide a vigorous amount of combustion in the first stage but only feed the coal without oxygen in the second stage to allow the endothermic gasification process to occur downstream of the second stage. One of the merits of this 2-stage practice is to keep the gasifier temperature low downstream from the 2nd stage. This helps to extend the life of refractory bricks, decrease gasifier shut-down frequency for scheduled maintenance, and reduce the maintenance costs. In this traditional 2-stage practice, the temperature reduction in the second stage is achieved at the expense of a higher than normal temperature in the first stage. This study investigates a concept totally opposite to the traditional two-stage coal feeding practices in which the injected oxygen is split between the two stages, while all the coal is fed into the first stage. The hypothesis of this two-stage oxygen injection is that a distributed oxygen injection scheme can also distribute the release of heat to a larger gasifier volume and, thus, reduce the peak temperature distribution in the gasifier. The increased life expectancy and reduced maintenance of the refractory bricks can prevail in the entire gasifier and not just downstream from the second stage. In this study, both experiments and computational simulations have been performed to verify the hypothesis. A series of experiments conducted at 2.5 - 3.0 bars shows that the peak temperature and temperature range in the gasifier do decrease from 600?C - 1550?C with one stage oxygen injection to 950?C - 1230?C with a 60 - 40 oxygen split-injection. The CFD results conducted at 2.5 bars show that 1) the carbon conversion ratio for different oxygen injection schemes are all above 95%;2) H2 (about 70% vol.) dominates the syngas composition at the exit;3) the 80% - 20% case yields the lowest peak temperature and the most uniform temperature distribution along the gasifier;and 4) the 40% - 60% case produces the syngas with the highest HHV. Both experimental data and CFD predictions verify the hypothesis that it is feasible to reduce the peak temperature and achieve more uniform temperature in the gasifier by adequately controlling a two-stage oxygen injection with only minor changes of the composition and heating value of the syngas.

Simulation of Ash Deposition Behavior in an Entrained Flow Coal Gasifier

Fly ash deposition is an important phenomenon associated with ash/slag handling and discharge in the entrained-flow coal gasification process. Fouling and slagging inside the gasifier may cause reliability and safety problems because they can impose strong negative effects on the gasifier wall in the way of heat transfer and chemical corrosion. For these reasons, this study focuses on investigating the ash deposition distribution inside of a two-stage entrained-flow gasifier. The computational model is developed in order to simulate the gasification process with a focus on modeling ash formation, fly ash, and ash deposition. The Eulerian-Lagrangian approach is applied to solve the reactive thermal-flow field and particle trajectories with heterogeneous reactions. The governing equations include the Navier-Stokes equations, twelve species transport equations, and ten global chemical reactions consisting of three heterogeneous reactions and seven homogeneous reactions. The coal/ash particles are tracked with the Lagrangian method. The effects of different coal/ash injection schemes and different coal types on ash deposition have been investigated. The results show that the two-stage fuel feeding scheme could distribute the ash throughout a larger gasifier’s volume and, hence, could reduce the peak ash deposition rate and make the ash distribution more uniform inside the gasifier. Gasification of a high-ash coal results in a high ash deposition rate, low syngas higher heating value (HHV), and low carbon conversion rate. The result of ash deposition rate in this study can be used as a boundary condition to provide ash particle influx distribution for use in slagging models.

Characterization of Size and Density Separated Fractions of a Bituminous Coal as a Feedstock for Entrained Slagging Gasification

Coal is one of the main sources of energy in many parts of the world and has one of the largest reserves/production ratios amongst all the non-renewable energy sources. Gasification of coal is one among the advanced technologies that has potential to be used in a carbon constrained economy. However, gasification availability at several commercial demonstrations had run into problems associated with fouling of syngas coolers due to unpredictable flyash formation and unburnt carbon losses. Computer models of gasifiers are emerging as a powerful tool to predict gasifier performance and reliability, without expensive testing. Most computer models used to simulate gasifiers tend to model coal as a homogenous entity based on bulk properties. However, coal is a heterogeneous material and comminution during feedstock preparation produces particle classes with different physical and chemical properties. It is crucial to characterize the heterogeneity of the feedstocks used by entrained flow gasifiers. To this end, a low ash US bituminous coal that could be used as a gasifier feedstock was segregated into density and size fractions to represent the major mineral matter distributions in the coal. Float and sink method and sieving were employed to partition the ground coal. The organic and inorganic content of all density fractions was characterized for particle size distribution, heating value, ultimate analysis, proximate analysis, mineral matter composition, ash composition, and petrographic components, while size fractions were characterized for heating value, ash composition, ultimate and proximate analysis. The proximate, ultimate and high heating value analysis showed that variation in these values is limited across the range of size fractions, while the heterogeneity is significant over the range of density fractions. With respect to inorganics, the mineral matter in the heavy density fractions contribute significantly to the ash yield in the coal while contributing very little to its heating value. The ash yield across the size fractions exhibits a bimodal distribution. The heterogeneity is also significant with respect to the base-to-acid ratio across the size and density fractions. The results indicate that the variations in organic and inorganic content over a range of density and size classes are significant, even in the low ash, vitrinite rich coal sample characterized here. Incorporating this information appropriately into particle population models used in gasifier simulations will significantly enhance their accuracy of performance predictions.

Shell煤气化炉气氛下熔渣中金属铁析出及对其黏度影响的模拟研究

气流床煤气化过程中,煤中无机矿物质升温熔融转变为熔渣,熔渣通过液态排渣单元连续排出炉外,因此熔渣良好的流动性(黏度)是气化炉长周期稳定运行的关键。我国高铁煤(煤灰中氧化铁的质量分数高于15%)分布广泛,比如内蒙古锡林浩特煤、河南义马煤、云南镇雄煤等。由于Shell煤气化炉内还原性气体(CO和H2)的总体积分数较高(>86%),高铁熔渣在液态排渣过程中易发生金属铁析出,形成大的含铁渣块,导致气化炉无法顺畅排渣甚至非正常停车,因此深入研究Shell煤气化炉气氛下熔渣中金属铁的析出行为是高铁熔渣流动性调控的重要依据。基于此,以热力学模拟为基础,依据金属铁析出和团聚机理,结合熔渣结晶特性,建立熔渣中金属铁析出和团聚的动力学模型,并定量分析金属铁对熔渣结晶和黏度的影响。热力学模拟表明,Shell煤气化炉气氛下高铁熔渣发生金属铁析出,且氧化钙的质量分数增加促进金属铁析出。分别以熔渣中还原性气体扩散和金属铁沉降为速控步骤,建立金属铁析出和团聚的动力学模型;氧化钙的质量分数增加或者温度升高,熔渣黏度降低,促进熔渣中还原性气体扩散,金属铁的质量分数增加且易发生团聚。提出金属铁团聚的临界时间作为判断金属铁团聚的关键参数;降低气化炉排渣温度或减少氧化钙的质量分数,金属铁团聚临界时间增加,避免熔渣中金属铁团聚。将晶体体积分数的热力学平衡值引入结晶动力学模型(KJMA公式),获得金属铁对熔渣结晶和黏度的影响,发现金属铁析出促进钙长石结晶,熔渣黏度迅速增加;虽然较低排渣温度下钙长石的体积分数达到热力学平衡值所需时间更长,但黏度增加至排渣黏度上限25 Pa·s所需的时间更短。建议通过适当降低排渣温度,或添加富硅助剂,或与高硅煤共气化,可适当避免高铁熔渣中金属铁的析出和团聚,避免熔渣黏度突增和气化炉排渣不畅,有利于气化炉长周期运行。

Implementation of a Demoisturization and Devolatilization Model in Multi-Phase Simulation of a Hybrid Entrained-Flow and Fluidized Bed Mild Gasifier

A mild gasification process has been implemented to provide an alternative form of clean coal technology called the Integrated Mild Gasification Combined Cycle (IMGCC), which can be utilized to build a new, highly efficient, and compact power plant or to retrofit an existing coal-fired power plant in order to achieve lower emissions and significantly improved thermal efficiency. The core technology of the mild gasification power plant lies on the design of a compact and effective mild gasifier that can produce synthesis gases with high energy volatiles through a hybrid system: utilizing the features of both entrained-flow and fluidized bed gasifiers. To aid in the design of the mild gasifier, a computational model has been implemented to investigate the thermal-flow and gasification process inside this mild gasifier using the commercial CFD (Computational Fluid Dynamics) solver ANSYS/FLUENT. The Eulerian-Eulerian method is employed to model both the primary phase (air) and the secondary phase (coal particles). However, the Eulerian-Eulerian model used in the software does not facilitate any built-in devolatilization model. The objective of this study is therefore to implement a devolatilization model (along with demoisturization) and incorporate it into the existing code. The Navier-Stokes equations and seven species transport equations are solved with three heterogeneous (gas-solid) and two homogeneous (gas-gas) global gasification reactions. Implementation of the complete model starts from adding demoisturization first, then devolatilization, and then adding one chemical equation at a time until finally all reactions are included in the multiphase flow. The result shows that the demoisturization and devolatilization models are successfully incorporated and a large amount of volatiles are preserved as high-energy fuels in the syngas stream without being further cracked or reacted into lighter gases. The overall results are encouraging but require future experimental data for verification.

气化炉内熔渣流动特性预测模型的研究进展

双碳战略目标下,煤气化技术将会是我国未来煤炭领域的重要发展路线。在煤气化技术推广应用中,熔渣的流动行为严重影响气化炉的平稳运行时长,间接影响合成气的质量和炉壁的热量损失,有效求解流动参数的熔渣流动特性预测模型备受关注。本研究论述了现有的气化炉内熔渣流动特性的预测模型,并展望了预测模型的未来研究方向。综述当下,预测模型根据熔渣流动维数可分为一维预测模型和二维预测模型;一维稳态和非稳态预测模型均经历了构建和完善阶段;二维预测模型因无相关的数学公式描述和流动理念假设尚处于构建阶段;通过对液态熔渣的温度分布、附加应力的取舍,临界黏度的选取和熔渣黏度的处理方式等方面可以提高模型的计算精度。展望未来,一维预测模型的应用场景需更完善的规定,针对稳态和非稳态预测模型求解的参数需要更细致的辨析;二维预测模型的构建理论需更详细的突破,明确非稳态工况下熔渣在轴向和周向上流动的优先级;流动预测模型的计算精度需更全面的提升,熔渣性质的非恒定性、熔化的不均匀性、烟气流速的波动性等因素需要侧重考虑。

煤气化渣资源化利用综述

随着“双碳”目标的推进,社会对煤气化渣处理的关注与需求日渐紧迫。综合过往研究,介绍了煤气化渣的主要来源与排渣方式,并分别对比了粗渣与细渣在形貌、粒度组成、矿物物相、化学组成等方面的性质特点,为实现其“减量化、资源化、无害化”利用提供了理论依据。基于气流床煤气化粗渣、细渣显著的性质差异,探索了两者不同的资源化处理方式,并分析了当下利用途径存在的局限性。粗渣具有优秀的水化活性与火山灰活性,在矿井回填、路基填筑、水泥与混凝土骨料、陶粒材料以及墙体材料等中低值利用领域应用广泛,但存在重金属浸出风险、经济效益低等问题。细渣中残炭含量丰富,主要采用重选法与浮选法进行可燃体回收与灰渣分离。但其较高的细粒级含量降低了重选分选精度,复杂的炭-灰结合形态提高了浮选回收难度。同时细渣孔隙结构发达,比表面积高达258.29 m^(2)/g,具有一定的吸附能力,在土壤改良、催化剂载体、化工原料、陶瓷材料、吸附材料等领域应用潜力巨大,但高值化处理工艺复杂,成本较高,工业应用难度较大。针对这些问题,需基于煤气化渣的物化性质,探索大规模消纳与高值化利用相结合的途径,实现对煤气化渣分类分级的资源化利用。此外,需结合现场生产实践,探索煤气化渣就地解决的处理方法以降低运输成本,以及在其产生工艺过程中进行物化性质的诱导改善处理。

Shell加压粉煤气流床气化技术的开发和应用

介绍了荷兰Ｓｈｅｌｌ加压粉煤气流床气化技术的开发过程及位于荷兰南部林堡省（Ｌｉｍｂｕｒｇ）的Ｄｅｍｋｏｌｅｃ采用Ｓｈｅｌｌ气化工艺建成的目前世界上最大的ＩＧＣＣ示范厂的工艺流程、运行状况和下一步发展展望。

Texaco和Shell煤气化工艺用于生产甲醇的经济性比较

新一代煤气流床气化工艺主要以Texaco水煤浆气化工艺和Shell干煤粉气化工艺为代表。Shell煤气化工艺操作温度可达1700℃,对煤种适应性高,碳转化率达99%以上。Texaco煤气化工艺的碳转化率为96%～98%。生产每吨甲醇,Shell气化工艺的煤耗量为1.25～1.28t,Texaco气化工艺为1.31～1.40t;Shell气化工艺的氧耗量比Texaco工艺低15%～25%;Shell工艺的总能耗(包括原料煤在内)为51.981GJ,比Texaco工艺低11.21GJ。然而,Shell煤气化工艺的投资高,以60×104t/a甲醇装置为例,Shell工艺的总投资为109242万元,Texaco工艺为85444万元;采用Shell工艺生产的甲醇总成本为1373元/t,比Texaco工艺的1277元/t高出约7.5%。同时,Shell工艺装置工业运行稳定性还需要进一步经工业化验证,而Texaco气化工艺在国内已有十几年的生产使用经验,其操作稳定性很高。通过总体经济性比较,在用于甲醇生产时,Shell煤气化工艺相对于Texaco煤气化工艺是没有优势的。

采用Shell加压粉煤气化技术改造我国大、中型氨厂的评价(上)

介绍了Shell和Texaco煤气化工艺的流程 ,并就两者的主要设备、对煤质的要求及用煤的处理和工艺性能进行了比较。

SHELL粉煤加压气化与新型水煤浆加压气化技术改造我国大中型氨厂的技术评价

SHELL粉煤加压气化与新型水煤浆气化技术都是高效低污染的先进煤气化方法。本文简要介绍了这两种技术的工艺原理、技术特点及开发现状,并指出了这两种煤气化工艺技术在改造我国大中型氨厂领域内的应用前景。

Shell煤气化耐硫变换工艺流程研究

针对Ｓｈｅｌｌ 煤气化的工艺特点，研究新的气化工艺技术给ＣＯ 变换流程带来的变化，进行ＣＯ 耐硫变换工艺流程设计，阐述余热回收应考虑的问题并提出新见解。

Shell煤气化技术及其在我国的应用

Shell煤气化技术历经30多年的发展,已成为当今世界上先进的洁净煤气化技术之一。介绍了Shell煤气化技术的发展历程、技术特点、目前国内应用中存在的一些问题以及国内引进装置的建设和投产情况。

采用Shell加压粉煤气化技术改造我国大、中型氨厂的评价(下)

分析了Shell粉煤气化装置运行的可靠性 ,就我国洞庭氮肥厂和柳州氮肥厂采用Shell粉煤气化技术改造方案及经济效益进行了说明 ,并与采用德士古气化技术改造的投资进行了比较。

Shell粉煤加压气化与新型水煤浆气化技术改造我国大、中型氨厂的技术评价

简要介绍了壳牌煤粉加压气化与新型水煤浆气化技术的工艺原理、技术特点及开发现状,指出了这两种煤气化工艺技术在改造我国大、中型氨厂领域内的应用前景。

Shell粉煤气化高水气比CO耐硫变换工艺流程优化

详细介绍了与Shell粉煤气化相配套的高水气比CO耐硫变换工艺流程,结合实际生产阐述了高水气比变换流程在运行中暴露出的问题,分析了问题的原因,提出了优化的Shell粉煤气化CO变换流程。

壳牌煤气化技术优化与评估

分析了壳牌煤气化技术优化与评估的措施。综述了壳牌煤气化技术的应用现状,探讨了其技术工艺流程和工艺系统。针对技术效率提升,提出了优化煤烧嘴角度、增强压缩机激冷能力以及改进吹灰器和敲击器设计等措施。探讨了提高煤粉利用率、优化合成气冷却过程及提升系统自动化水平等降成本措施。建立了层次结构模型,确定了优化气化技术的评价标准和子标准,进行了风险评估,得出所提优化措施能有效提升壳牌煤气化技术的效率,并能降低成本。提出了优化后技术的实施计划、资源配置、技术支持及风险评估与应对措施,为壳牌煤气化技术的持续优化和应用提供了指导。

一次风率对煤粉气流床气化-燃烧特性及NO_(x)排放影响的试验研究

煤粉气化-燃烧技术是实现燃煤锅炉超低负荷稳燃和低氮氧化物(NO_(x))排放的重要方式。为了揭示一次风率(λ_(1))对煤粉气化-燃烧特性及NO_(x)排放的影响。采用自主搭建的对冲气流床气化-燃烧系统,研究了λ_(1)对煤粉气化特性,燃料N转化和NO_(x)排放特性的影响,采用热重分析仪和化学吸附仪对气化半焦的反应性和孔隙结构进行分析。结果表明:λ_(1)的增加会提高气化炉温度,使气化炉出口CO和CH_(4)的浓度分别降低了2.67%和2.43%;促进了固定碳的转化,其转化率增加了17.28%;燃料N的转化率增加了13.50%,其中增加了向N_(2)的转化,但降低了向NH_(3)的转化。同时,λ_(1)增加使气化焦炭具有更发达的孔隙结构,比表面积增加了95.77 m^(2)/g,孔体积增加了2倍,改善了气化焦炭的燃烧特性。气化燃料进入燃烧室后,当λ_(1)高于0.25时,燃烧室主燃区内未生成NO。λ_(1)为0.35时,燃烧室出口的污染物排放最低,NO_(x)和CO分别为115.86 mg/Nm^(3)(@6%O_(2))和39.25 mg/Nm^(3)(@6%O_(2));此时燃烧效率最高,为99.68%。因此,一次风对煤粉气化燃烧特性和污染物排放具有显著的影响,控制合适的一次风量可以降低污染物排放的同时提升燃烧效率。