TEKNOLOGI PEMBUATAN ADSORBEN DARI LIMBAH EKSTRAKSI BIOSILIKA SEKAM PADI

PFTJ Pasundan Food Technology Journal Pub Date : 2020-12-05 DOI:10.23969/pftj.v7i3.3001

Hoerudin Sri Usmiati Prima Luna, Sunarmani Balai, Besar Penelitian, Dan Pengembangan, Pascapanen Pertanian

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Abstract

Adsorbent from lignocellulosic waste constitutes an alternative in industry due to the large amount and easy to get. The unique characteristics of activated carbon from lignocellulosic waste as well as more economically with regard to mass production were the reasons for the development of by-products of this rice husk biosilica waste. This research aimed to produce adsorbent from waste of nanobiosilica powder extraction. Calcination or treatment without impregnation) and with impregnation were applied in this study. Calcination was carried out by heating the residual waste at 600 ° C; 700 ° C; and 800 ° C; however the impregnation process was carried out by immersing the residual waste with catalysts ZnCl2, H3PO4, and KOH with ratio 1: 1 and 1: 2 for 24 hours. Subsequently, carbonisation was carried out at 600 ° C; 700 ° C; and 800 ° C for 1 and 3 hours with variations in mesh sizes of 10, 20, 80, and 100 mesh. The results showed that the waste of nanobiosilica extraction still contained high SiO2 (89.86%) so that it could be used as raw material for adsorber to apply in water purification applications. The calcination treatment showed the highest absorption as well as the area of the pore surface. The best particle size was 100 mesh and calcined at 800 ° C in which has a pore surface area meet the requirement of commercial activated charcoal, which is 15.83 m² / g.

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从稻壳中提取生物硅胶废物中培养的技术

从木质纤维素废料中提取吸附剂因其用量大、易于获得而成为工业上的一种替代品。木质纤维素废弃物中活性炭的独特特性和大规模生产的经济性是开发稻壳生物二氧化硅废弃物副产品的原因。本研究旨在利用纳米生物硅粉萃取废渣制备吸附剂。本研究采用了煅烧(不浸渍)和浸渍处理。在600℃下对残废进行煅烧;700℃;800℃;采用ZnCl2、H3PO4、KOH三种催化剂分别以1:1和1:1的比例浸泡24h的浸渍工艺。随后，在600℃下进行碳化;700℃;和800°C 1和3小时，在10,20,80和100目的网格尺寸变化。结果表明，纳米生物二氧化硅萃取后的废渣中SiO2含量仍然很高(89.86%)，可以作为吸附剂的原料用于水净化。煅烧处理的吸收率和孔表面积均最高。最佳粒径为100目，800℃煅烧，其孔表面积为15.83 m²/ g，符合商品活性炭的要求。

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PFTJ Pasundan Food Technology Journal

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审稿时长

24 weeks