Citric Acid-Treated Zeolite Y (CY)/Zeolite Beta Composites as Supports for Vacuum Gas Oil Hydrocracking Catalysts: High Yield Production of Highly-Aromatic Heavy Naphtha and Low-BMCI Value Tail Oil

Wei, Qiang; Zhang, Jiarui; Liu, Xiaodong; Zhang, Pengfei; Wang, Shuqin; Wang, Yan; Zhang, Zhenli; Zhang, Tao; Zhou, Yasong

doi:10.3389/fchem.2019.00705

Cited by 9 publications

(2 citation statements)

References 49 publications

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“…Generally speaking, the acid modification of Hβ zeolites can well clean the pores inside the zeolites, and is a common method for the pretreatment of Hβ zeolites. − Therefore, in this work, three types of Hβ zeolites were acid-modified before further use. To determine whether acid treatment would destroy the original structure of Hβ zeolites, the framework structure and crystallinity of Hβ zeolites before and after acid modification were characterized by XRD.…”

Section: Resultsmentioning

confidence: 99%

Solid-Phase Synthesis of Polysaccharides from Unprotected Glucose Catalyzed by Hβ Zeolites

Dong

Xiao

Zhang

et al. 2022

ACS Sustainable Chem. Eng.

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Polysaccharide is a kind of biological macromolecule with a complex structure, which plays an irreplaceable role in the organism. Due to the complex purification process of natural polysaccharide, chemical synthesis is an important means to obtain it. In this work, a green and efficient solid-phase polymerization method was used to synthesize glucan polysaccharide from unprotected glucose in one step under mild solid-phase conditions, using Hβ zeolites as acidic catalyst. The final polysaccharide product was characterized by high-performance liquid chromatography (HPLC) and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF-MS) with a conversion of 35.0% and a maximum degree of polymerization of 26. More importantly, it was speculated that the glycosylation of unprotected glucose catalyzed by Hβ zeolites conforms to the Fischer glycosylation mechanism. In addition, the results of methylation analysis and one-dimensional, twodimensional nuclear magnetic resonance (1D, 2D NMR) showed that the resulting polysaccharides were mainly linear, containing 10 different glycosidic linkages, and (1,6-Glcp), (1-Glcp), and (1,4-Glcp) were the most abundant linkage types among them.

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Section: Resultsmentioning

confidence: 99%

Solid-Phase Synthesis of Polysaccharides from Unprotected Glucose Catalyzed by Hβ Zeolites

Dong

Xiao

Zhang

et al. 2022

ACS Sustainable Chem. Eng.

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“…Diverse contents of β were used by Wei et al [20] in catalyst carrier when mixing two types of zeolites (β and citric acid treated Y) without terminating the original textural properties of each one. Since several acid sites were reacted or covered by other sites throughout amalgamation procedure, the acidity deviated from linearly estimated theoretical data.…”

Section: Influence Of Zeolite Propertiesmentioning

confidence: 99%

Catalytic advances in vacuum gas oil hydrocracking

Мухтарова¹,

Guliyeva²,

Ahmadova³

2022

SOCAR Proceedings

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Hydrocracking still maintains the pivotal role in the industry owing to the production of highly demanded transportation fuels. Having comprised pretreatment of VGO, comparative research onrecent catalysts, this review paper provides athorough picture about all consecutive steps in the hydrocracking process of vacuum gasoil. Discussing recovery of VGO from vacuum residue with minimum sulfur content, the focus was put on the catalyst characterizations and their influence on the conversion of VGO, the yield of middle distillate, gasoline as well asnaphtha. Both zeolite and amorphous catalysts have undergone a comparative analysis interms of their hydrocracking properties as well as catalytic activities during provided conditions. The article also examines the process of hydrocracking of vacuum gas-oil from Baku oils with the participation of modified aluminosilicate catalyst containing Ni, Mo to obtain high-quality raw materials for environmentally friendly diesel fuel and catalytic cracking process. The hydrocracking process of vacuum gas-oil conducted at 3-8 MPa pressure, 400-450 °C temperature range, in a flow-type Hungarian unit with a reactor capacity of 200 ml. During the investigations of temperature on hydrocracking process it was revealed that, when temperature rises from 400 to 460 °С the yield of diesel fraction increases from 35 to 50% wt. The yield of gasoline fraction constitutes 0-6% wt. and the produce of residue fraction decreases from 65% to 45%. With increasing of temperature from 400 °C to 450 °C the amount of sulphur decreases from 0.01% to 0.005% in composition of diesel fraction. Keywords: vacuum gasoil; hydrocracking; diesel fraction; alumosilicate; catalyst; hydrodesulfurization.

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Catalytic Conversion of 2‐Phenethyl Phenyl Ether and 2‐Phenoxy‐1‐Phenyl Ethanol Over ZSM‐5, Y and Beta Zeolites

Le,

Pham,

et al. 2024

ChemistrySelect

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Catalytic conversion of 2‐phenoxy‐1‐phenyl ethanol (PPE‐OH) and 2‐phenethyl phenyl ether (PPE) was conducted in an autoclave reactor using Faujasite zeolite (HY), Beta zeolite (HBEA), and Zeolite Socony Mobil‐5 (HZSM‐5) with medium and large pore channels. All catalysts were thoroughly analyzed using various techniques like FT‐IR, N2 physisorption, XRD, SEM‐EDX, NH3‐TPD, ICP spectroscopy, and thermogravimetric analysis (TGA). The results showed that HBEA and HY catalysts, with their larger pore channels and sizes, exhibited excellent activity in breaking the ether bond of PPE‐OH. HBEA and HY zeolites exhibited almost full conversion of PPE‐OH at 240 °C and 1 h, and HZSM‐5 zeolite obtained only 47% conversion of PPE‐OH at the same condition. The cleavage of the ether bond of β‐O‐4 linkage was performed over HBEA and HY zeolites better than HZSM‐5 zeolite. Moreover, high‐strong acid sites of HBEA zeolite favored breaking PPE at 240 °C and 1 h, and PPE did not convert over HY and HZSM‐5 zeolites at the same condition. These findings highlight the crucial role of pore size and channels and the acidity of catalysts for converting large molecules like lignin. This study provides valuable insights into using zeolite catalysts for breaking down the β‐O‐4 linkage in lignin.

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Citric Acid-Treated Zeolite Y (CY)/Zeolite Beta Composites as Supports for Vacuum Gas Oil Hydrocracking Catalysts: High Yield Production of Highly-Aromatic Heavy Naphtha and Low-BMCI Value Tail Oil

Cited by 9 publications

References 49 publications

Solid-Phase Synthesis of Polysaccharides from Unprotected Glucose Catalyzed by Hβ Zeolites

Solid-Phase Synthesis of Polysaccharides from Unprotected Glucose Catalyzed by Hβ Zeolites

Catalytic advances in vacuum gas oil hydrocracking

Catalytic Conversion of 2‐Phenethyl Phenyl Ether and 2‐Phenoxy‐1‐Phenyl Ethanol Over ZSM‐5, Y and Beta Zeolites

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