{"title":"从原油真空残渣中提取石墨碳","authors":"Ravi Dalsania , Hasmukh Gajera , Mahesh Savant","doi":"10.1016/j.cartre.2024.100424","DOIUrl":null,"url":null,"abstract":"<div><div>Preparation of graphitic carbon from low value refinery waste has captivated immense interest in past years owing to its low cost and abundant nature. Successful utilization of petroleum vacuum residue is a major challenge in the petroleum industry. In this study pyrolysis of vacuum residue fractions has been carried out for the preparation of graphitic carbon like material. The vacuum residue fractions were obtained from three different crude oils originated from Middle East, Canada and South America. The purity of the Aromatic, Resin and Asphaltene (ARA) fractions were confirmed using TLC-FID which denoted complete separation. The chemical composition were determined using elemental analysis and it revealed ARA fractions to be carbon rich regardless of its origin. Further, sulphur content was found to be high in ARA fractions from Heavy Crude oil (HCO). The degree of polymerization and molecular weight measured using GPC specify that asphaltene has high accumulation with high molecular weight compared with aromatic and resins. ARA derived carbon and heat-treated materials were analysed by TGA, XRD and Raman spectroscopy to study microstructural changes in formation of graphite like material. Thermogravimetric analysis of all ARA samples revealed the different decomposition stages for pyrolyzed, calcined and graphitized samples. The results of XRD demonstrated that the distance between the planes (d-spacing) is above 3.35 Å for all high temperature treated ARA derived carbon materials irrespective of its origin, indicating formation of graphite like structure. In Raman analysis, the nature and intensity of G and D bands evolution during each step of pyrolysis is supporting XRD results for formation of highly ordered graphitic carbon material. Furthermore, understanding feed quality has direct influence on high efficiency, low costs and sustainability, the major issues for oil refinery business.</div></div>","PeriodicalId":52629,"journal":{"name":"Carbon Trends","volume":"17 ","pages":"Article 100424"},"PeriodicalIF":3.1000,"publicationDate":"2024-11-05","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Exploration of graphitic carbon from crude oil vacuum residue\",\"authors\":\"Ravi Dalsania , Hasmukh Gajera , Mahesh Savant\",\"doi\":\"10.1016/j.cartre.2024.100424\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><div>Preparation of graphitic carbon from low value refinery waste has captivated immense interest in past years owing to its low cost and abundant nature. Successful utilization of petroleum vacuum residue is a major challenge in the petroleum industry. In this study pyrolysis of vacuum residue fractions has been carried out for the preparation of graphitic carbon like material. The vacuum residue fractions were obtained from three different crude oils originated from Middle East, Canada and South America. The purity of the Aromatic, Resin and Asphaltene (ARA) fractions were confirmed using TLC-FID which denoted complete separation. The chemical composition were determined using elemental analysis and it revealed ARA fractions to be carbon rich regardless of its origin. Further, sulphur content was found to be high in ARA fractions from Heavy Crude oil (HCO). The degree of polymerization and molecular weight measured using GPC specify that asphaltene has high accumulation with high molecular weight compared with aromatic and resins. ARA derived carbon and heat-treated materials were analysed by TGA, XRD and Raman spectroscopy to study microstructural changes in formation of graphite like material. Thermogravimetric analysis of all ARA samples revealed the different decomposition stages for pyrolyzed, calcined and graphitized samples. The results of XRD demonstrated that the distance between the planes (d-spacing) is above 3.35 Å for all high temperature treated ARA derived carbon materials irrespective of its origin, indicating formation of graphite like structure. In Raman analysis, the nature and intensity of G and D bands evolution during each step of pyrolysis is supporting XRD results for formation of highly ordered graphitic carbon material. 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引用次数: 0
摘要
过去几年,从低价值炼油废料中制备石墨碳因其成本低、资源丰富而备受关注。成功利用石油真空残渣是石油工业面临的一大挑战。本研究对真空残渣馏分进行了热解,以制备类似石墨碳的材料。真空残渣馏分来自中东、加拿大和南美洲的三种不同原油。芳烃、树脂和沥青质(ARA)馏分的纯度使用 TLC-FID 进行确认,结果表明完全分离。通过元素分析确定了化学成分,结果表明 ARA 馏分富含碳元素,无论其来源如何。此外,还发现来自重质原油(HCO)的 ARA 馏分中硫含量较高。使用 GPC 测量的聚合度和分子量表明,与芳香烃和树脂相比,沥青烯具有较高的累积量和较高的分子量。通过热重分析、X 射线衍射和拉曼光谱对 ARA 衍生碳和热处理材料进行了分析,以研究形成类似石墨材料的微观结构变化。对所有 ARA 样品进行的热重分析表明,热解、煅烧和石墨化样品处于不同的分解阶段。X 射线衍射结果表明,所有经过高温处理的 ARA 衍生碳材料,无论其来源如何,平面间距(d-spacing)都超过了 3.35 Å,表明形成了类似石墨的结构。在拉曼分析中,每一步热解过程中 G 和 D 波段演变的性质和强度都证明了 XRD 的结果,即形成了高度有序的石墨碳材料。此外,了解原料质量对高效率、低成本和可持续发展有直接影响,而这正是炼油厂业务面临的主要问题。
Exploration of graphitic carbon from crude oil vacuum residue
Preparation of graphitic carbon from low value refinery waste has captivated immense interest in past years owing to its low cost and abundant nature. Successful utilization of petroleum vacuum residue is a major challenge in the petroleum industry. In this study pyrolysis of vacuum residue fractions has been carried out for the preparation of graphitic carbon like material. The vacuum residue fractions were obtained from three different crude oils originated from Middle East, Canada and South America. The purity of the Aromatic, Resin and Asphaltene (ARA) fractions were confirmed using TLC-FID which denoted complete separation. The chemical composition were determined using elemental analysis and it revealed ARA fractions to be carbon rich regardless of its origin. Further, sulphur content was found to be high in ARA fractions from Heavy Crude oil (HCO). The degree of polymerization and molecular weight measured using GPC specify that asphaltene has high accumulation with high molecular weight compared with aromatic and resins. ARA derived carbon and heat-treated materials were analysed by TGA, XRD and Raman spectroscopy to study microstructural changes in formation of graphite like material. Thermogravimetric analysis of all ARA samples revealed the different decomposition stages for pyrolyzed, calcined and graphitized samples. The results of XRD demonstrated that the distance between the planes (d-spacing) is above 3.35 Å for all high temperature treated ARA derived carbon materials irrespective of its origin, indicating formation of graphite like structure. In Raman analysis, the nature and intensity of G and D bands evolution during each step of pyrolysis is supporting XRD results for formation of highly ordered graphitic carbon material. Furthermore, understanding feed quality has direct influence on high efficiency, low costs and sustainability, the major issues for oil refinery business.