Carburization of High-Temperature Alloys during Steam Cracking: The Impact of Alloy Composition and Temperature

Shirazi, Hamed Mohamadzadeh; Ghanbari, Arezoo; Vermeire, Florence H.; Reyniers, Marie-Françoise

doi:10.1021/acs.iecr.2c03599

Cited by 3 publications

(13 citation statements)

References 47 publications

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“…The Al-Boosted, demonstrated higher resistance to coke formation compared to the aluminum-free alloys, Spinel-Coated and 35/45 Cr–Ni. This finding aligns with previous experimental studies on ethane steam cracking, ,, which also highlighted the superior fouling resistance of Al-containing alloys.…”

Section: Resultssupporting

confidence: 92%

“…As shown in Section , the preoxidation step was not performed with the Spinel-Coated alloy because the alloy is already preoxidized during the manufacturing process. These results show that additional preoxidation might be needed for this alloy, as well …”

Section: Resultsmentioning

confidence: 70%

“…EDX mapping analysis performed on the cross-sectional area of Al-Boosted after five cracking cycles with ethane and butane feeds illustrates why the amount of coke and the catalytic coking rate are lower for this alloy than for the other nonaluminum materials. Carbon did not diffuse into the bulk, and no evidence of internal oxidation was observed, a detrimental phenomenon in cracking of aluminum-containing alloys that results in poor resistance to carburization . The integrity of the alumina layer formed during preoxidation is still visible after several coking/decoking cycles, indicating the excellent resistance of this alloy to carburization.…”

Section: Resultsmentioning

confidence: 96%

“…Carbon did not diffuse into the bulk, and no evidence of internal oxidation was observed, a detrimental phenomenon in cracking of aluminum-containing alloys that results in poor resistance to carburization. 38 The integrity of the alumina layer formed during preoxidation is still visible after several coking/decoking cycles, indicating the excellent resistance of this alloy to carburization. This thin (ca.…”

Section: Sem and Edx Analysesmentioning

confidence: 93%

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Effect of Reactor Alloy Composition on Coke Formation during Butane and Ethane Steam Cracking

Mohamadzadeh Shirazi,

dos Santos Vargette,

Reyniers

et al. 2024

Ind. Eng. Chem. Res.

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The use of highly specialized alloys in ethane steam cracking environments can lead to reduced coking and alloy aging. However, the fouling resistance of these materials when exposed to heavier feedstocks, such as butane, especially at higher temperatures (950 °C) and toward the end of a cracking run, remained unknown. To address this knowledge gap, this study investigated the coke resistances of presulfided three alloys, Al-Boosted, Spinel-Coated, and 35/45 Cr−Ni, during the steam cracking of both ethane and butane using a quartz Electrobalance setup with a tubular reactor. Under experimental conditions of T gas = 950 °C, P = 1.1 bar, χ Butane ≈ 79%, χ Ethane ≈ 68%, dilution δ = 0.4 kg Hd 2 O /kg HC , and DMDS = 48 ppmw S/HC, the results revealed that butane cracking exhibited higher coking compared to ethane for the Al-Boosted and 35/45 Cr−Ni. This difference was attributed to the generation of larger quantities of coke precursors, such as aromatics, naphthenes, and butadiene, during butane cracking. Notably, the Alcontaining alloy displayed exceptional resistance to aging, in contrast to the non-Alcontaining alloys, which experienced severe carburization and aging effects after multiple cracking cycles. Detailed scanning electron microscopy (SEM) and energy-dispersive X-ray (EDX) analyses indicated that the presence of a continuous and robust Al 2 O 3 layer on the surface of the Al-containing alloy provided significant protection to the catalytic sites within the material. The average catalytic coking rate for the Al-containing alloy during butane cracking was measured at 5.83 × 10 −6 kg m −2 s −1 , while for the non-Alcontaining alloys, it ranged from 7.26 × 10 −6 to 15.25 × 10 −6 kg m −2 s −1 . Furthermore, this study explored the relative influence of the feedstock and reactor material, revealing that for the Al-Boosted alloy, the feedstock had a greater impact on coking behavior. Conversely, for the 35/45 Cr−Ni alloy, aging had a more pronounced effect compared to that of the specific feedstock used. This research provides valuable insights into the fouling behavior of specialized alloys in the steam cracking of ethane and butane. The study highlights the superior resistance to aging and reduced coking rate exhibited by the Al-containing alloy, underscoring the protective role of the Al 2 O 3 layer. Additionally, it emphasizes the relative significance of both feedstock composition and reactor material on coking tendencies, thereby contributing to a better understanding of fouling mechanisms in the steam cracking process.

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Section: Resultssupporting

confidence: 92%

Section: Resultsmentioning

confidence: 70%

Section: Resultsmentioning

confidence: 96%

Section: Sem and Edx Analysesmentioning

confidence: 93%

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Effect of Reactor Alloy Composition on Coke Formation during Butane and Ethane Steam Cracking

Mohamadzadeh Shirazi,

dos Santos Vargette,

Reyniers

et al. 2024

Ind. Eng. Chem. Res.

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“…Causes of pyrolysis furnace failure include carburization, creep, high-temperature oxidation, thermal fatigue, thermal shock, and other damage. Failures caused by carburization are especially common [1][2][3][4]. The statistical results of the investigation of ethylene pyrolysis furnace tube failure in Japan [5] showed that more than half of pyrolysis furnace tube damage was caused by carburization pyrolysis.…”

Section: Introductionmentioning

confidence: 99%

Carburizing Rate of Pyrolysis Furnace Tube in Long-term Service

Du,

Liu,

et al. 2023

J. Phys.: Conf. Ser.

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The high-temperature working environment of ethylene pyrolysis furnace tubes makes carburization one of the main damage mechanisms, and carburization also leads to the degradation of tube material properties and failure. It is important to study the carburization rate of long-term service furnace tubes for the evaluation of long-cycle use and carburization detection. In this paper, the relationship between carburization rate and carburization time is studied by low-pressure vacuum carburization of Cr35Ni45Nb alloy tubes with different service life (new tubes, two years, three years, and six years) in the field, aiming to provide a scientific basis for the remaining life prediction and carburization inspection for the tube material.

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Coke Formation in Steam Cracking Reactors: Deciphering the Impact of Aromatic Compounds and Temperature on Fouling Dynamics

Mohamadzadeh Shirazi,

dos Santos Vargette,

Bellos

et al. 2024

Ind. Eng. Chem. Res.

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Formation of coke poses a considerable challenge in steam cracking reactors utilized for olefin production, exerting detrimental effects on the reactor performance and productivity. To tackle this challenge, a more profound understanding of fouling phenomena and their intricate connections with feedstock composition and process conditions is imperative. While conventional wisdom suggests that all aromatics contribute to increased coke formation, our research challenges this assumption. To evaluate this assumption, an investigation was conducted to measure the coking tendency of single-ring aromatics, double-ring aromatics, and naphtheno-diaromatic compounds by introducing them to a naphtha sample. On one hand, the incorporation of single-ring aromatics, up to 9 wt %, resulted in a 12% reduction in the overall coke formation rate across the radiant and TLE sections. Conversely, the introduction of 2 wt % double-ring aromatics exhibited a marginal 4% increase in coking rates. However, the introduction of a naphtheno-diaromatic compound led to a 35% increase in coke formation rates in the radiant and TLE sections. On the other hand, temperature emerged as a more significant factor influencing coke formation within steam cracking reactions. Elevating the coil outlet temperature (COT) from 950 to 970 °C resulted in a minimum 40% rise in the asymptotic coking rates. This study underscores the importance of comprehending coke formation mechanisms in steam cracking reactors and developing effective methods to mitigate fouling.

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Carburization of High-Temperature Alloys during Steam Cracking: The Impact of Alloy Composition and Temperature

Cited by 3 publications

References 47 publications

Effect of Reactor Alloy Composition on Coke Formation during Butane and Ethane Steam Cracking

Effect of Reactor Alloy Composition on Coke Formation during Butane and Ethane Steam Cracking

Carburizing Rate of Pyrolysis Furnace Tube in Long-term Service

Coke Formation in Steam Cracking Reactors: Deciphering the Impact of Aromatic Compounds and Temperature on Fouling Dynamics

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