Heptane Reforming over Pt–Re/Al2O3: Reaction Network, Kinetics, and Apparent Selective Catalyst Deactivation

Liu, Ke; Fung, S.C.; Ho, Teh C.; Rumschitzki, David S.

doi:10.1006/jcat.2001.3485

Cited by 36 publications

(15 citation statements)

References 13 publications

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“…Ring closure of n-heptane is much faster than that of nhexane [17], while according to Marin et al i-hexnaes do not cyclize to form corresponding homologs [14]. Liu et al [46] reported that the rate of cyclization of i-heptanes was negligible when compared to n-heptane. Ancheyeta et al [19] reported that paraffins cyclize more easily as their molecular weight increases.…”

Section: 1mentioning

confidence: 97%

Toward enhanced hydrogen production in a catalytic naphtha reforming process

Stijepović

Linke

Alnouri

et al. 2012

International Journal of Hydrogen Energy

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Section: 1mentioning

confidence: 97%

Toward enhanced hydrogen production in a catalytic naphtha reforming process

Stijepović

Linke

Alnouri

et al. 2012

International Journal of Hydrogen Energy

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“…Prema Froment-u i saradnicima [13], i-heksan ne podleže reakcijama dehidrociklizacije. Takođe, prema istraživanjima Lui i saradnika [74], brzina reakcije dehidrociklizacije i-heptana je zanemarljiva u odnosu na brzinu reakcije dehidrociklizacije n-heptana. Na bazi zaključaka o reaktivnost i-heksana i i-heptana do kojih su došli Froment i saradnici [13] i Lui i saradnici [74], očekivano je da i-okatni imaju manju reaktivnost od n-oktana.…”

Section: Formulisanje Kinetičkog Modelaunclassified

“…Takođe, prema istraživanjima Lui i saradnika [74], brzina reakcije dehidrociklizacije i-heptana je zanemarljiva u odnosu na brzinu reakcije dehidrociklizacije n-heptana. Na bazi zaključaka o reaktivnost i-heksana i i-heptana do kojih su došli Froment i saradnici [13] i Lui i saradnici [74], očekivano je da i-okatni imaju manju reaktivnost od n-oktana. Međutim, prema istraživanjima Ako i Susa [75] brzina dehidrociklizacije i-oktana je mnogo veća nego n-oktana.…”

Section: Formulisanje Kinetičkog Modelaunclassified

“…U literaturi je razmatran problem formiranja koksa [69][70][71]74,[87][88][89][90][91]. Međutim, ne postoji veliki broj radova [70,71,90,91] Određivanje konstante hemijske ravnoteže K j prikazano je u delu 3.1, trećeg poglavlja ove disertacije.…”

Section: Kinetički Modeli Reakcija Katalitičkog Reforminga Benzina I unclassified

“…Kao što je rečeno, prema modelu Liu i saradnika [74], brzina formiranja koksa zavisi od koncentracija vodonika i alkilciklopentana. Brzina formiranja matematički je opisana diferencijalnom jednačinom .…”

Section: Slika 42 šEmatski Prikaz Reaktora Sa Pokretnim Slojemunclassified

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Modeling and energy optimization of the catalytic naphtha reforming process

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Non Monotonous Product Distribution Dependence on Pt/γ‐Al₂O₃−Cl Catalysts Formulation in n‐Heptane Reforming.

et al. 2020

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The synthesis of 19 carefully selected Pt/γ-Al 2 O 3 À Cl formulations was followed by high-throughput catalytic testing in order to unravel the effect of an active phase formulation change on nheptane reforming performances. Pt/γ-Al 2 O 3 À Cl catalysts were prepared with different Pt (0.3-1 % wt ) and Cl (0.1-1.4 % wt ) contents and using two γ-Al 2 O 3 supports so that both sites concentrations and sites locations at the crystallite surface vary among the catalyst pool. Catalytic tests were conducted in mild conditions for a comparison of catalysts in kinetic regime.Results show that Pt and Cl concentrations control the competition between hydroisomerisation, hydrogenolysis and hydrocracking pathways. Aromatisation, on the contrary, is poorly affected by formulation changes. Non-monotonous trends linking Pt/Cl ratio to isomerisation selectivity are found for both γ-Al 2 O 3 supports. This study provides new insights for the description of bi-functional transformations in catalytic naphtha reforming.

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Heptane Reforming over Pt–Re/Al2O3: Reaction Network, Kinetics, and Apparent Selective Catalyst Deactivation

Cited by 36 publications

References 13 publications

Toward enhanced hydrogen production in a catalytic naphtha reforming process

Toward enhanced hydrogen production in a catalytic naphtha reforming process

Modeling and energy optimization of the catalytic naphtha reforming process

Non Monotonous Product Distribution Dependence on Pt/γ‐Al₂O₃−Cl Catalysts Formulation in n‐Heptane Reforming.

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Heptane Reforming over Pt–Re/Al2O3: Reaction Network, Kinetics, and Apparent Selective Catalyst Deactivation

Cited by 36 publications

References 13 publications

Toward enhanced hydrogen production in a catalytic naphtha reforming process

Toward enhanced hydrogen production in a catalytic naphtha reforming process

Modeling and energy optimization of the catalytic naphtha reforming process

Non Monotonous Product Distribution Dependence on Pt/γ‐Al2O3−Cl Catalysts Formulation in n‐Heptane Reforming.

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Product

Resources

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Non Monotonous Product Distribution Dependence on Pt/γ‐Al₂O₃−Cl Catalysts Formulation in n‐Heptane Reforming.