共查询到20条相似文献,搜索用时 78 毫秒
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在使用CIE1931标准色度学系统定义的色度坐标(x,y)对煤粉燃烧火焰的颜色进行定量试验研究的基础上,本文通过计算比较,提出了可用于锅炉燃烧诊断的煤粉火焰颜色色度坐标近似计算方法。 相似文献
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煤粉燃烧火焰区域是燃烧过程中温度最高的区域,同时也是温度梯度、组分浓度梯度最高的地方,以及还原和氧化气氛交错存在等复杂环境,这种环境对亚微米颗粒初始形成阶段有着重要的影响,对该区域形成的PM1进行研究有助于深入理解PM1的形成机理.本文基于25 kW一维下行炉内对自维持燃烧的煤粉火焰区域,通过两级稀释水冷等速取样系统和ELPI(荷电低压撞击分离器)系统对颗粒物进行分级收集,以及电镜分析技术,获得PM1的质量和数浓度粒径分布,以及各粒径主要成分分布,并进行单颗粒分析.结果表明火焰区域中形成的亚微米颗粒以含碳物质为主,碳烟、碱金属和硫对超细颗粒有富集的趋势.该区域的亚微米颗粒同时存在多种复杂的形成机理. 相似文献
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煤粉燃烧火焰辐射光谱实验研究 总被引:1,自引:0,他引:1
针对煤粉燃烧辐射光谱问题,利用光纤光谱仪对煤粉平面火焰炉实验装置煤粉燃烧火焰辐射光谱进行了测量,详细分析了煤粉辐射光谱特征,并基于普朗克辐射传热定律,通过对光谱仪波长响应特性的标定,得到火焰绝对辐射强度随波长的分布情况,进而利用最小二乘法获得火焰温度与辐射率参数,由此提出基于煤粉燃烧火焰辐射光谱测量的火焰参数测量方法。利用该方法对不同燃烧条件下煤粉燃烧参数进行测量,开展了不同燃烧参数下煤粉火焰辐射光谱实验研究,研究结果表明:煤粉燃烧火焰辐射在200~1 100 nm波段具有较强且连续的光谱特征,基于普朗克辐射定律与最小二乘法可实现煤粉燃烧火焰温度与辐射率的测量;煤粉燃烧火焰辐射光谱在590,766,769和779 nm附近可见明显的Na和K等碱金属痕量元素原子光谱发射谱线,并且这些原子谱线的出现与火焰温度有关;随着煤粉浓度的提高,虽然燃烧温度变化不大,但由于火焰辐射率的增加,造成辐射光谱强度的大幅提升。这对锅炉煤粉燃烧优化具有重要参考价值。 相似文献
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1引言目前煤粉燃烧综合模型最为广泛的是以轨道模型为基础,美国杨伯翰大学的先进燃烧工程中心(CERC)自1980年起研制二维煤粉燃烧程序PCGC-2,从1990年起研制三维煤粉燃烧的PCGC-3程序[1]。与轨道模型发展的同时,美国Rabcock&Wilcox公司Fiveland[2]等人研制了FURMO程序,用无滑移模型对560MW侧墙喷燃煤粉炉进行了三维全模拟。其特点是首次用全欧拉的处理方法计算三维煤粉燃烧过程,其不足之处是不考虑气粒两相间的速度滑移和温度滑移.总的看来,用轨道模型模拟煤粉燃烧,易于考虑颗粒反应经历,也可给出两相之间的速度及温… 相似文献
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如何模拟液体燃料的雾化、掺混及燃烧过程,一直以来都备受关注。本文试图将无网格MPS(moving particlesemi-implicit rnethod)方法与颗粒轨道模型结合起来描述液体燃料从射流、破碎、雾化、输运全过程,并与基于Euler网格气相方程耦合求解,从而可以获得对雾化燃烧全过程模拟的一体化方法。初步结果显示,其方法和技术路线可行。 相似文献
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分别采用标量联合的概率密度函数方法、稳态火焰面模型、Euler非稳态火焰面模型和基于有限体积/Monte Carlo混合算法的完备PDF模型对钝体驻定的Sydney湍流扩散火焰HM1进行数值模拟,以比较不同燃烧模型的性能,并比较标量联合的概率密度函数方法和Euler非稳态火焰面模型对氮氧化物排放预测的差异.计算结果和实验数据的比较表明,采用概率密度函数方法计算化学反应可以得到更好的结果但计算量较大,而用火焰面模型求解计算量较小,在接近完全燃烧的情形下,其计算结果比较合理. 相似文献
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Simulation of Combustion Field with Lattice Boltzmann Method 总被引:5,自引:0,他引:5
Turbulent combustion is ubiquitously used in practical combustion devices. However, even chemically non-reacting turbulent flows are complex phenomena, and chemical reactions make the problem even more complicated. Due to the limitation of the computational costs, conventional numerical methods are impractical in carrying out direct 3D numerical simulations at high Reynolds numbers with detailed chemistry. Recently, the lattice Boltzmann method has emerged as an efficient alternative for numerical simulation of complex flows. Compared with conventional methods, the lattice Boltzmann scheme is simple and easy for parallel computing. In this study, we present a lattice Boltzmann model for simulation of combustion, which includes reaction, diffusion, and convection. We assume the chemical reaction does not affect the flow field. Flow, temperature, and concentration fields are decoupled and solved separately. As a preliminary simulation, we study the so-called counter-flow laminar flame. The particular flow geometry has two opposed uniform combustible jets which form a stagnation flow. The results are compared with those obtained from solving Navier–Stokes equations. 相似文献
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利用火焰发射光谱来研究汽油机的燃烧过程 总被引:2,自引:0,他引:2
本文用一套精密的光电转换系统,采集了一台汽油机燃烧过程中火焰辐射在可见光到近紫外波段内的光谱,探测到了燃烧中间产物CH、CN、C2、H2O等的特征光谱,并分析了这些产物在燃烧过程中的变化规律,以及随过量空气系数,缸内压力的变化.实验结果表明,汽油机三个不同的燃烧阶段具有不同的燃烧光谱特征:着火过程中,存在着大量的处于激发态的分子、原子、离子、自由基等活化中心的束缚态光谱,随着燃烧发展,CH、C2自由基的光谱强度明显加强;当减小过量空气系数时,光谱强度变弱并且着火延迟期增长;自由基特征光谱的光强变化曲线可以反映它们在燃烧过程中的浓度变化.所以火焰发射光谱是实时检测燃烧中间产物,特别是CH、C2等有害排放物变化规律的有效手段,可以为分析、模拟燃烧过程,控制排放提供有用的实验数据. 相似文献
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Ying Huang Grant A. Risha Vigor Yang Richard A. Yetter 《Proceedings of the Combustion Institute》2007,31(2):2001-2009
The combustion of bimodal nano/micron-sized aluminum particles with air is studied both analytically and experimentally in a well-characterized laminar particle-laden flow. Experimentally, an apparatus capable of producing Bunsen-type premixed flames was constructed to investigate the flame characteristics of bimodal-particle/air mixtures. The flame speed is positively affected by increasing the mass fraction of nano particles in the fuel formulation despite the lower flame luminosity and thicker flame zone. Theoretically, the flames are assumed to consist of several different regimes for fuel-lean mixture, including the preheat, flame, and post flame zones. The flame speed and temperature distribution are derived by solving the energy equation in each regime and matching the temperature and heat flux at the interfacial boundaries. The analysis allows for the investigation of the effects of particle composition and equivalence ratio on the burning characteristics of aluminum-particle/air mixtures. Reasonable agreement between theoretical results and experimental data was obtained in terms of flame speed. The flame structure of a bimodal particle dust cloud may display either an overlapping or a separated configuration, depending on the combustion properties of aluminum particles at different scales. At low percentages of nano particles in the fuel formulation, the flame exhibits a separated spatial structure with a wider flame regime. At higher nano-particle loadings, overlapping flame configurations are observed. 相似文献