The Adsorptive Purification Of Low-Quality Glycerin By Biocarbon Adsorbents

Salikhanova Dilnoza Saidakbarovna; Savrieva Dilafruz Doutovna; Ismailova Mukhtasar Abdumutalib kizi; Sagdullaeva Dilafruz Saidakbarovna; Abdurakhimov Akhror Anvarovich; Karabaeva Muslima Iftikhorovna

Authors

Salikhanova Dilnoza Saidakbarovna Doctor of Technical Sciences, Senior Researcher, Institute of General and Inorganic Chemistry of the Academy of Sciences of the Republic of Uzbekistan, Uzbekistan
Savrieva Dilafruz Doutovna Institute of General and Inorganic Chemistry, Academy of Sciences of the Republic of Uzbekistan, Uzbekistan
Ismailova Mukhtasar Abdumutalib kizi PhD, Institute of General and Inorganic Chemistry, Academy of Sciences of the Republic of Uzbekistan, Uzbekistan
Sagdullaeva Dilafruz Saidakbarovna Doctor of Technical Sciences, Senior Researcher, Institute of Bioorganic Chemistry of the Academy of Sciences of the Republic of Uzbekistan, Uzbekistan
Abdurakhimov Akhror Anvarovich Doctor of Technical Sciences, Tashkent Chemical-Technological Institute, Uzbekistan
Karabaeva Muslima Iftikhorovna Doctoral candidate (DSc), International Institute of Food Technologies and Engineering, Uzbekistan

Keywords:

Glycerin, adsorbent, impurities

Abstract

This study investigates the purification of low-quality glycerin using biocarbon adsorbents derived from cherry pits. The carbon adsorbent produced (ACCP) demonstrated superior efficacy in reducing glycerin color, decreasing it from 10 mg I₂/100 cm³ to 5 mg I₂/100 cm³, outperforming the imported coconut carbon adsorbent (ACC), which only achieved a reduction to 6 mg I₂/100 cm³. It has also been established that a carbon adsorbent with a particle size of 2-3 mm is considered optimal, as smaller particles hinder filtration, thereby increasing ash content due to the migration of fine carbon particles into the filtrate. A reduction in the acid number by 5-6 times allows for an improvement in the quality of glycerin and extends its shelf life. It has been determined that the carbon adsorbent derived from cherry pits selectively reduces the amount of free fatty acids. Initial glycerin parameters corresponded to grade T-88 specifications; however, after treatment with the synthesized adsorbents, the parameters improved to meet the D-98 standard requirements. These findings suggest that cherry pit-based adsorbents are a promising alternative for purifying glycerin in various industrial applications.

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The Adsorptive Purification Of Low-Quality Glycerin By Biocarbon Adsorbents

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