Development of beneficiation technique for bentonite for applications in petroleum industry

Bentonite from Andrassy and Mansuli area of Sabah had been proven containing higher impurity minerals than commercial bentonite used in petroleum industry. This study comprises an optimum beneficiation process to upgrade the quality of Sabah bentonite by removal of iron and quartz content from it. S...

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Main Author:	Irawan, Sonny
Format:	Thesis
Language:	English
Published:	2006
Subjects:	TP Chemical technology
Online Access:	http://eprints.utm.my/id/eprint/2741/1/SonnyIrawanPFKT2006.pdf
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spelling	my-utm-ep.27412018-10-14T08:19:05Z Development of beneficiation technique for bentonite for applications in petroleum industry 2006-06 Irawan, Sonny TP Chemical technology Bentonite from Andrassy and Mansuli area of Sabah had been proven containing higher impurity minerals than commercial bentonite used in petroleum industry. This study comprises an optimum beneficiation process to upgrade the quality of Sabah bentonite by removal of iron and quartz content from it. Several organic acids have been studied but only the oxalic acid can successfully be used. Oxalic acid can be produced by fermentation with filamentous fungi such as Aspergillus and Penicillium, using as substrate residues with high organic carbon content. The exhaust fermentation medium can be the extracting agent for dissolving the bentonite iron-oxides. This process is economically favourable; besides producing effluents which are easy to purify. Other parameters that included in this study are oxalic acid concentration, beneficiation time, temperature and pH. In general, the optimum conditions for Andrassy and Mansuli samples beneficiation process occurred at an oxalic acid concentration of 7.1 Kg m-3 with 2 hours beneficiation time, temperature at 80Â°C, and a pH less than 2. The results obtained after beneficiation indicated that the content of the montmorillonite mineral from Andrassy and Mansuli sample show improvement with increment from 47 % to 258 % of the original value. The maximum associated silica and iron oxide released with gravitational process are in the range of 2.51% to 11.92% and 1.38% to 13.33%, respectively. The Liquid limit, plastic limit and plasticity index improved varying from 89.82% to 229.63%, 0.40% to 37.13% and 181.78% to 582.57%, respectively. The moisture content and moisture absorption increased in the range of 9.92% to 63.33% and 3.42% to 79.26%, respectively. The cation exchange capacity improved in the range of 22.45 % to 58.54 % and the specific surface area increment from 17% to 104.50%. However, the upgraded sample failed to fulfil the API (American Petroleum Institute) requirements for rheological properties when used as a material in drilling mud and an additive for oilwell cement. Thereafter, certain polymer dispersant had been added to improve rheological properties of the upgraded Sabah bentonite slurry so that it can be used as a drilling mud material and as oilwell cement additive. The YP/PV ratio of the beneficiated samples with addition of 1% to 4% wt Tannathin successfully met the API 13A and 10A requirement. The fluid loss of the beneficiated sample reduced when 2% to 2.5% wt of Tannathin was added. Generally, the degree of improvement of bentonite quality mainly depend on the origin of bentonite itself, itâ€™s composition, chemical used in the beneficiation process and itâ€™s concentration, beneficiation time, temperature and pH of the solution 2006-06 Thesis http://eprints.utm.my/id/eprint/2741/ http://eprints.utm.my/id/eprint/2741/1/SonnyIrawanPFKT2006.pdf application/pdf en public http://dms.library.utm.my:8080/vital/access/manager/Repository/vital:60669 phd doctoral Universiti Teknologi Malaysia, Faculty of Chemical and Natural Resources Engineering Faculty of Chemical and Natural Resources Engineering
institution	Universiti Teknologi Malaysia
collection	UTM Institutional Repository
language	English
topic	TP Chemical technology
spellingShingle	TP Chemical technology Irawan, Sonny Development of beneficiation technique for bentonite for applications in petroleum industry
description	Bentonite from Andrassy and Mansuli area of Sabah had been proven containing higher impurity minerals than commercial bentonite used in petroleum industry. This study comprises an optimum beneficiation process to upgrade the quality of Sabah bentonite by removal of iron and quartz content from it. Several organic acids have been studied but only the oxalic acid can successfully be used. Oxalic acid can be produced by fermentation with filamentous fungi such as Aspergillus and Penicillium, using as substrate residues with high organic carbon content. The exhaust fermentation medium can be the extracting agent for dissolving the bentonite iron-oxides. This process is economically favourable; besides producing effluents which are easy to purify. Other parameters that included in this study are oxalic acid concentration, beneficiation time, temperature and pH. In general, the optimum conditions for Andrassy and Mansuli samples beneficiation process occurred at an oxalic acid concentration of 7.1 Kg m-3 with 2 hours beneficiation time, temperature at 80Â°C, and a pH less than 2. The results obtained after beneficiation indicated that the content of the montmorillonite mineral from Andrassy and Mansuli sample show improvement with increment from 47 % to 258 % of the original value. The maximum associated silica and iron oxide released with gravitational process are in the range of 2.51% to 11.92% and 1.38% to 13.33%, respectively. The Liquid limit, plastic limit and plasticity index improved varying from 89.82% to 229.63%, 0.40% to 37.13% and 181.78% to 582.57%, respectively. The moisture content and moisture absorption increased in the range of 9.92% to 63.33% and 3.42% to 79.26%, respectively. The cation exchange capacity improved in the range of 22.45 % to 58.54 % and the specific surface area increment from 17% to 104.50%. However, the upgraded sample failed to fulfil the API (American Petroleum Institute) requirements for rheological properties when used as a material in drilling mud and an additive for oilwell cement. Thereafter, certain polymer dispersant had been added to improve rheological properties of the upgraded Sabah bentonite slurry so that it can be used as a drilling mud material and as oilwell cement additive. The YP/PV ratio of the beneficiated samples with addition of 1% to 4% wt Tannathin successfully met the API 13A and 10A requirement. The fluid loss of the beneficiated sample reduced when 2% to 2.5% wt of Tannathin was added. Generally, the degree of improvement of bentonite quality mainly depend on the origin of bentonite itself, itâ€™s composition, chemical used in the beneficiation process and itâ€™s concentration, beneficiation time, temperature and pH of the solution
format	Thesis
qualification_name	Doctor of Philosophy (PhD.)
qualification_level	Doctorate
author	Irawan, Sonny
author_facet	Irawan, Sonny
author_sort	Irawan, Sonny
title	Development of beneficiation technique for bentonite for applications in petroleum industry
title_short	Development of beneficiation technique for bentonite for applications in petroleum industry
title_full	Development of beneficiation technique for bentonite for applications in petroleum industry
title_fullStr	Development of beneficiation technique for bentonite for applications in petroleum industry
title_full_unstemmed	Development of beneficiation technique for bentonite for applications in petroleum industry
title_sort	development of beneficiation technique for bentonite for applications in petroleum industry
granting_institution	Universiti Teknologi Malaysia, Faculty of Chemical and Natural Resources Engineering
granting_department	Faculty of Chemical and Natural Resources Engineering
publishDate	2006
url	http://eprints.utm.my/id/eprint/2741/1/SonnyIrawanPFKT2006.pdf
_version_	1747814430455889920

Development of beneficiation technique for bentonite for applications in petroleum industry

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