棕榈仁壳（PKS）基棕榈仁壳油生物柴油催化剂的制备与表征

Q1 Social Sciences

South African Journal of Chemical Engineering Pub Date : 2025-02-20 DOI:10.1016/j.sajce.2025.02.008

E.O. Babatunde , S. Enomah , O.M. Akwenuke , M.A. Ibeh , C.O. Okwelum , M.M. Mundu , P.O. Adepoju , A.O. Aki , O.D. Oghenejabor , T.F. Adepoju , C.O. Ifedora , K. Mabel

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引用次数: 0

摘要

截至2023年至2024年，全球棕榈油产量的比例为7946万吨。具体来说，90%的棕榈树生物量被浪费了，只有10%的油棕产品是由棕榈仁油制成的。大多数研究结论表明，PKS作为合成气和生物柴油的生物燃料，以及作为生物吸附剂、磨料、解毒、抗菌、抗真菌和抗氧化物质，具有巨大的潜力。因此，在催化煅烧的棕榈仁壳灰存在的情况下，本研究使用棕榈仁中的甘蔗渣作为棕榈仁油的生物吸附剂，用于生产生物燃料。截至2023年至2024年，全球棕榈油产量的比例为7946万吨。具体来说，90%的棕榈树生物量被浪费了，只有10%的油棕产品是由棕榈仁油制成的。大多数研究结论表明，PKS作为一种生物燃料具有巨大的潜力，可用于生产合成气和生物柴油，以及生物吸附剂、磨料、解毒、抗菌、抗真菌和抗氧化物质。因此，在催化煅烧的棕榈仁壳灰存在的情况下，本研究使用棕榈仁中的甘蔗渣作为棕榈仁油的生物吸附剂，用于生产生物燃料。采用确定筛选设计（DSD），综合考虑反应温度、反应时间、CSKP浓度、甲醇-油摩尔比（MOH/OMR） 4个因素对工艺进行改进。这些变量引起了13次实验运行。结果表明，甘蔗渣作为生物吸附剂可将高酸性油脂转化为低酸性油脂。发现K>；Mg>Ca> Na>；Mn存在于发育的CSKP中。在67.574 min的反应时间、67.116 min的反应温度、3.957 %的CKSP （wt.）和1:7.989的MOH/OMR（100%期望的100个结果）下，生物燃料产率为99.73% （wt/wt.）。三次实验运行验证了预测值，发现平均值为99.65% （wt./wt.）。这种催化剂可以回收利用，所产生的生物燃料等级显示出很高的能源潜力。根据这项研究的发现，棕榈仁果废料有可能被用作制造生物柴油的原料。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Preparation and characterization of Palm Kernel Shell (PKS) based biocatalyst for the transformation of kernel oil to biodiesel

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Preparation and characterization of Palm Kernel Shell (PKS) based biocatalyst for the transformation of kernel oil to biodiesel

The proportion of palm oil produced worldwide as of 2023–2024 was 79.46 million metric tons. Specifically, 90 % of the biomass from palm trees is wasted, and only 10 % of the total oil palm products are made from palm kernel oil. The majority of research' conclusions show that PKS has enormous potential as a bio-fuel for the generation of syngas and biodiesel, as well as a bio-adsorbent, abrasive, detoxifying, antibacterial, antifungal, and antioxidant substance. Thus, in the presence of catalytically calcined kernel shell ash, this study uses bagasse from palm kernels as a bio-adsorbent of palm kernel oil for the production of biofuel. The proportion of palm oil produced worldwide as of 2023–2024 was 79.46 million metric tons. Specifically, 90 % of the biomass from palm trees is wasted, and only 10 % of the total oil palm products are made from palm kernel oil. The majority of research's conclusions show that PKS has enormous potential as a biofuel for the generation of syngas and biodiesel, as well as a bio-adsorbent, abrasive, detoxifying, antibacterial, antifungal, and antioxidant substance. Thus, in the presence of catalytically calcined kernel shell ash, this study uses bagasse from palm kernels as a bio-adsorbent of palm kernel oil for the production of biofuel.

Using definite screening design (DSD), the procedure was improved by taking into account four factors: reaction temperature, reaction duration, CSKP concentration, and methanol-oil-molar- ratio (MOH/OMR). These variables give rise to thirteen experimental runs. The ability of kernel shell bagasse to function as a bio-adsorbent for the transformation of high-acidity oil into low-acidity oil was demonstrated by the results. K>Mg>Ca>P>Na>Mn was discovered to be present in the developed CSKP. A biofuel yield of 99.73 % (wt/wt.) at a reaction time of 67.574 min, a reaction temperature of 67.116 min, a CKSP of 3.957 % (wt.), and a MOH/OMR of 1:7.989 in 100 outcomes at 100 % desirability were projected using statistical process optimization. Three experimental runs were used to validate the projected value, and an average value of 99.65 % (wt./wt.) was found. The catalyst can be recycled, and the biofuel grade that was created showed a high potential for energy.

According to the study's findings, palm kernel fruit wastes have the potential to be used as a raw material to make biodiesel.

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来源期刊

South African Journal of Chemical Engineering Social Sciences-Education

CiteScore

8.40

自引率

0.00%

发文量

100

审稿时长

33 weeks

期刊介绍： The journal has a particular interest in publishing papers on the unique issues facing chemical engineering taking place in countries that are rich in resources but face specific technical and societal challenges, which require detailed knowledge of local conditions to address. Core topic areas are: Environmental process engineering • treatment and handling of waste and pollutants • the abatement of pollution, environmental process control • cleaner technologies • waste minimization • environmental chemical engineering • water treatment Reaction Engineering • modelling and simulation of reactors • transport phenomena within reacting systems • fluidization technology • reactor design Separation technologies • classic separations • novel separations Process and materials synthesis • novel synthesis of materials or processes, including but not limited to nanotechnology, ceramics, etc. Metallurgical process engineering and coal technology • novel developments related to the minerals beneficiation industry • coal technology Chemical engineering education • guides to good practice • novel approaches to learning • education beyond university.