Pyrolysis and coking behavior of typical liquid hydrocarbon fuels in hot pipe

doi:10.11949/0438-1157.20231190

Abstract

Abstract:

The fuel molecular structure is an important factor affecting the pyrolysis coking process in the active cooling channel. Stripping the effect of turbulent diffusion on pyrolysis coking, the pyrolysis coking patterns of typical aviation kerosene components such as n-heptane (nC₇H₁₆), iso-heptane (iC₇H₁₆), methylcyclohexane (MCH), n-dodecane (nC₁₂H₂₆), and toluene (A₁CH₃) were compared in a pre-oxidized STS304 (Φ3.0 mm×0.5 mm×1.0 m, outer diameter × wall thickness × length) flow reactor tube at 600—800℃, 1.0 MPa, and under a laminar near-chemical kinetic state. The normalized molar fraction distributions of pyrolysis gas-liquid products of the five typical fuels were quantitatively obtained, and the unsteady-state coking characteristics and along-range coking distribution patterns of the fuels were compared by weighing method. The results show that the conversion of chain alkanes is higher at the lower temperature of 650℃, the conversion of MCH as well as A₁CH₃ is lower due to the stabilized cyclic structure, and the conversion of A₁CH₃ increases abruptly above 775℃. The hydrogen (H₂), methane (CH₄) content of iC₇H₁₆ and MCH is significantly higher due to the presence of branched methyl groups. Straight-chain alkanes have higher contents of ethylene (C₂H₄) and ethane (C₂H₆) through β-scission. Propylene (C₃H₆) is a by-product of C—C bond breakage. The content of C₃H₆ is higher at lower temperatures, while the content of C₂H₄ and C₃H₆ tends to decrease due to the secondary reaction of coking at high temperatures. The main products in the liquid phase included benzene, A₁CH₃, naphthalene and other diphenyl aromatic hydrocarbons. The content of polycyclic aromatic hydrocarbons (PAHs) increased at high temperatures, and tetraphenyl aromatic hydrocarbons such as perylene, phenanthrene, and anthracene were detected by GC-MS, but they accounted for a very low molar fraction of the bulk phase. The coking rates of MCH and nC₁₂H₂₆ were low at lower temperatures, and the coking rates of MCH and A₁CH₃ increased significantly at higher temperatures. Branched and long straight-chain alkanes favor high-temperature coking inhibition. Straight-chain alkane coking peaks at the beginning of the thermostatic zone, with coking by addition of unsaturated light hydrocarbons. MCH and A₁CH₃coking peaks are closer downstream, with coking by deposition of aromatic polymerization. Straight-chain alkanes have the highest content of cracked C₂H₄ and C₃H₆, which is conducive to providing high heat sink. The cleavage of nC₁₂H₂₆ firstly produces 1-olefins such as 1-dodecene, 1-undecene, 1-decene, 1-octene, 1-hexene, 1-pentene etc., and the deep cleavage of these 1-olefins produces C₂H₄ and C₃H₆etc. Since the depth of pyrolysis of long carbon-chain nC₁₂H₂₆ is lower than that of the short-chain nC₇H₁₆, it exhibits the heat sink that is even lower at high temperatures. Branched-chain alkanes are more stable than straight-chain alkanes and have a weaker tendency to form carbon deposition, but the presence of methyl group makes the product alkylated to a higher degree. The coking rates of the five typical hydrocarbon fuels were closely related to the temperature, showing a three-stage unsteady-state growth pattern, with differences in the location of the peak coking along the process. The coking rate of straight-chain alkanes was larger at low temperatures, and the contribution of MCH and A₁CH₃ coking was significantly higher at high temperatures.

Key words: hydrocarbons, molecular structure, pyrolysis, coking, heat sink

摘要：

燃料分子结构是影响主动冷却通道内热解结焦过程的重要因素。在预氧化的STS304（Φ3.0 mm×0.5 mm×1.0 m）流动反应管内，600~800℃、1.0 MPa下对比了正庚烷（nC₇H₁₆）、异庚烷（iC₇H₁₆）、甲基环己烷（MCH）、正十二烷（nC₁₂H₂₆）、甲苯（A₁CH₃）的热解结焦行为。实验定量获取了热解气液产物并计算了燃料反应热沉，通过称重法对比了非稳态结焦特性和沿程结焦分布规律。结果表明，较低温度650℃下链烷烃的转化率较高，环烷烃次之，A₁CH₃在高于775℃转化率骤增。低温下MCH和nC₁₂H₂₆结焦速率较低，高温下MCH和A₁CH₃的结焦速率显著提高。直链烷烃裂解双烯含量最高，稳定的环状结构均有利于提供高热沉。iC₇H₁₆比nC₇H₁₆更稳定且结焦趋向更弱，但甲基的存在，产物烷烃化程度增加。五种典型燃料的结焦过程均呈现三阶段非稳态生长规律，低温下链烷烃结焦速率较大，高温下MCH和A₁CH₃结焦贡献显著提高。

关键词: 碳氢化合物, 分子结构, 热解, 焦化, 热沉

CLC Number:

TQ 203.8

Haowen LI, Hao LAN, Youdan ZHENG, Yonghui SUN, Zixin YANG, Qianshi SONG, Xiaohan WANG. Pyrolysis and coking behavior of typical liquid hydrocarbon fuels in hot pipe[J]. CIESC Journal, 2024, 75(2): 626-636.

李浩文, 兰昊, 郑幼丹, 孙勇辉, 杨子昕, 宋谦石, 汪小憨. 热通道内典型碳氢燃料的热解结焦行为[J]. 化工学报, 2024, 75(2): 626-636.

Figures/Tables 11

Fig.1 Composition of conventional gasoline, diesel and aviation kerosene[12]

Fig.2 Schematic diagram of hydrocarbon fuel pyrolysis coking experimental system

Fig.3 Comparison of fuel conversion at different temperatures

Fig.4 Mole fraction of cracking products for different fuels at the outlet

Fig.5 GC-MS spectrum of liquid products of nC12H26 pyrolysis at 600—800°C

Fig.6 Schematic diagram of the initial cracking path of nC12H26

Fig.7 Physical heat sink and total heat sink of five fuels

Fig.8 Comparison of average coking rate of fuel at 600—800℃, 1.0 MPa, 40 min running time

Fig.9 Comparison of coke morphology of different fuels at 700°C and 40 min coking duration

Fig.10 Comparison of coking spatial distribution of different fuels and temperature distribution along the reaction tube at 700℃, 40 min running time

Fig.11 Evolution of non-stationary coking morphology of different fuels

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