PARAMETRIC OPTIMIZATION OF OIL PALM MESOCARP FIBER VALORIZATION WITH HYBRID OZONATION-ULTRASONIC PRETREATMENT METHOD

IF 0.6 Q3 ENGINEERING, MULTIDISCIPLINARY

IIUM Engineering Journal Pub Date : 2023-07-04 DOI:10.31436/iiumej.v24i2.2717

Didi Dwi Anggoro, I. Kusuma Dewi, Luqman Buchori, Aji Prasetyaningrum

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Abstract

Oil palm mesocarp fiber is a promising lignocellulosic biomass as a raw material for valorizing biomass into more valuable products such as second-generation biofuels, biocomposites, or bioenergy. However, the lignin composition present in lignocellulosic biomass provides resistance to the valorization process and protects the cellulose composition, thereby limiting the conversion of cellulose into more valuable products. The hybrid ozonation-ultrasonic method as a lignin-degrading method is starting to be considered an effective method. Additionally, a Box-Behnken Design (BBD) was employed to investigate each independent variable's effect on pretreatment process conditions using the response surface methodology (RSM), namely reaction time (30-90) min, reaction temperature (20 -40) oC and ozone flow rate (1-3) L/min to the response of the percentage of lignin degradation (%). The optimum condition of the pretreatment process is determined using the desirability function graph. The results showed that reaction time, reaction temperature, and ozone flow rate had a significant effect on lignin degradation (p <0.05). The optimum conditions obtained the highest percentage of lignin degradation, namely 92.08% at a reaction temperature of 30 oC with an ozone flow rate of 2 L/min for 60 minutes reaction time. The decrease in lignin absorption peaks at 1638 cm-1 and 1427 cm-1 was supported by the results of the analysis of increased crystallinity in the sample after the pretreatment of lignin degradation to 80.20% and was validated by changes in the morphology of the mesocarp fiber after the pretreatment process indicating that the lignin compound had been successfully degraded from cellulose products of mesocarp fibers. ABSTRAK: Sabut gentian kelapa sawit berpotensi sebagai bahan mentah biojisim lignoselulosa bagi menambah nilai produk biojisim seperti bahan bio api generasi kedua, biokomposit atau biotenaga. Walau bagaimanapun, komposisi lignin yang wujud dalam biojisim lignoselulosa menentang proses tambah nilai dan melindungi komposisi selulosa, dengan itu mengehadkan penukaran selulosa kepada produk yang lebih berharga. Kaedah hibrid ozonasi-ultrasonik sebagai kaedah merendahkan lignin, mula mendapat perhatian sebagai kaedah berkesan. Selain itu, Reka Bentuk Kotak-Behnken (BBD) telah digunakan bagi menyiasat setiap kesan pembolehubah bebas pada keadaan proses prarawatan menggunakan kaedah permukaan tindak balas (RSM), iaitu masa tindak balas (30-90) min, suhu tindak balas (20 -40) oC dan kadar aliran ozon (1-3) L/min terhadap tindak balas pada peratusan degradasi lignin (%). Keadaan optimum bagi proses prarawatan ditentukan menggunakan graf fungsi keboleh inginan. Dapatan kajian menunjukkan bahawa masa tindak balas, suhu tindak balas, dan kadar aliran ozon mempunyai kesan yang signifikan terhadap degradasi lignin (p<0.05). Keadaan optimum peratusan degradasi lignin tertinggi adalah pada 92.08% pada suhu tindak balas 30 oC dengan kadar aliran ozon 2 L/min selama 60 minit masa tindak balas. Penurunan puncak penyerapan lignin pada 1638 cm-1 dan 1427 cm-1 disokong oleh keputusan analisis peningkatan kehabluran sampel selepas prarawatan degradasi lignin sebanyak 80.20% dan telah disahkan oleh perubahan morfologi sabut gentian selepas proses prarawatan menunjukkan bahawa sebatian lignin telah berjaya didegradasi daripada produk selulosa sabut gentian.

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臭氧-超声复合预处理油棕中果皮纤维增值工艺参数优化

油棕中果皮纤维是一种很有前途的木质纤维素生物质原料，可以将生物质转化为更有价值的产品，如第二代生物燃料、生物复合材料或生物能源。然而，木质纤维素生物质中存在的木质素组成提供了对增值过程的抵抗力，并保护了纤维素组成，从而限制了纤维素转化为更有价值的产品。臭氧-超声复合降解木质素的方法开始被认为是一种有效的方法。此外，采用Box-Behnken设计(BBD)，利用响应面法(RSM)考察了各自变量对预处理工艺条件的影响，即反应时间(30-90)min、反应温度(20 -40)oC和臭氧流量(1-3)L/min对木质素降解率(%)的响应。利用期望函数图确定了预处理工艺的最佳条件。结果表明，反应时间、反应温度和臭氧流量对木质素降解有显著影响(p <0.05)。在反应温度为30℃，臭氧流速为2 L/min，反应时间为60 min的条件下，木质素的降解率最高，达到92.08%。木质素降解预处理至80.20%后，样品的结晶度增加，这一结果证实了木质素吸收峰在1638 cm-1和1427 cm-1处的下降，并通过预处理过程后中果皮纤维形态的变化证实了木质素化合物已经从中果皮纤维的纤维素产物中成功降解。摘要:龙胆、龙胆、龙胆、龙胆、龙胆、龙胆、龙胆、龙胆、龙胆、龙胆、龙胆、龙胆、龙胆、龙胆、龙胆、龙胆、龙胆、龙胆、龙胆、龙胆、龙胆、龙胆、龙胆、龙胆、龙胆、龙胆。木质素;木质素;木质素;木质素;木质素;木质素，木质素，木质素，木质素，木质素，木质素，木质素，木质素。Selain itu, Reka Bentuk Kotak-Behnken (BBD)， telah digunakan bagi menyiasat setiap kesan pembolehubah bebas paada keadaan proses prarawatan menggunakan kaedah permukaan tindak balas (RSM)， iitu masa tindak balas (30-90) min, suhu tindak balas (20 -40) oC和kadar aliran ozon (1-3) L/min, terhadap tindak balas paada peratusan降解木质素(%)。Keadaan最优bagi工艺:prawatan ditentukan menggunakan嫁接真菌Keadaan bolboleh inginan。Dapatan kajian menunjukkan bahawa masa tindak balas, suhu tindak balas, dan kadar aliran ozon mempunyai kesan yang对木质素的降解作用显著(p<0.05)。Keadaan最佳peratusan degradasi木质素tertinggi adalah篇92.08%篇苏沪tindak红晶石30 oC dengan阿提拉·aliran摄影机2 L / min selama 60 minit玛莎tindak红玉。Penurunan puncak penyerapan木质素pada 1638 cm-1和1427 cm-1 disokong oleh keputusan分析peningkatan kehabluran样品selepas prawatan降解木质素sebanyak 80.20%和telah disahkan oleh perubahan形态saban龙胆selepas加工prawatan menunjukkan bahawa sebatan木质素telah berjaya降解daripaada产品selulosa sabut龙胆。

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来源期刊

IIUM Engineering Journal ENGINEERING, MULTIDISCIPLINARY-

CiteScore

2.10

自引率

20.00%

发文量

审稿时长

40 weeks

期刊介绍： The IIUM Engineering Journal, published biannually (June and December), is a peer-reviewed open-access journal of the Faculty of Engineering, International Islamic University Malaysia (IIUM). The IIUM Engineering Journal publishes original research findings as regular papers, review papers (by invitation). The Journal provides a platform for Engineers, Researchers, Academicians, and Practitioners who are highly motivated in contributing to the Engineering disciplines, and Applied Sciences. It also welcomes contributions that address solutions to the specific challenges of the developing world, and address science and technology issues from an Islamic and multidisciplinary perspective. Subject areas suitable for publication are as follows: -Chemical and Biotechnology Engineering -Civil and Environmental Engineering -Computer Science and Information Technology -Electrical, Computer, and Communications Engineering -Engineering Mathematics and Applied Science -Materials and Manufacturing Engineering -Mechanical and Aerospace Engineering -Mechatronics and Automation Engineering