Obtaining a hematite pigment by thermal transformation of the surface oxide of reinforcing steel bars

Obtaining a hematite pigment by thermal transformation of the surface oxide of reinforcing steel bars

In this investigation work, the valuation of the surface oxide waste from reinforcing steel bars through to its thermal transformation into a pigment composed mainly of hematite (ɑ-Fe2O3) is reported. X-ray Fluorescence (XRF) and X-ray Diffraction (XRD) were used to determine the elemental content...

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Main Authors: María Angélica Colpas-Ruiz, Camilo Gnecco-Molina, José Pérez-Mendoza, Oscar Higuera-Cobos, Gabriel Jiménez-Rodríguez
Format: Article
Language:English
Published: Universidad Industrial de Santander 2020-05-01
Series:Revista UIS Ingenierías
Subjects:
ɑ-Fe2O3
iron oxide
pigment characterization
calcination
crystalline phases
Online Access:https://revistas.uis.edu.co/index.php/revistauisingenierias/article/view/10168
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spelling doaj-e8ef0c4b9a784d25bdc3e72bb340d4742020-11-25T03:03:50ZengUniversidad Industrial de SantanderRevista UIS Ingenierías1657-45832145-84562020-05-01193Obtaining a hematite pigment by thermal transformation of the surface oxide of reinforcing steel barsMaría Angélica Colpas-Ruiz0Camilo Gnecco-Molina1José Pérez-Mendoza2Oscar Higuera-Cobos3Gabriel Jiménez-Rodríguez4Universidad del AtlánticoUniversidad del AtlánticoUniversidad del AtlánticoUniversidad del AtlánticoUniversidad del Atlántico In this investigation work, the valuation of the surface oxide waste from reinforcing steel bars through to its thermal transformation into a pigment composed mainly of hematite (ɑ-Fe2O3) is reported. X-ray Fluorescence (XRF) and X-ray Diffraction (XRD) were used to determine the elemental content of the processed waste and identify the iron oxides involved in the calcination, respectively. The steelmaking waste powder is mainly composed by Fe2O3 (87.92 %), SiO2 (6.13 %), CaO (1.88 %), Al2O3 (1.30 %) and MnO (0.77 %). The total iron content corresponds to the following iron oxides: magnetite, maghemite, wustite, lepidocrocite, hematite and goethite. The thermal treatment of the residue at temperatures of 750-850 °C and holding times of 0.5-1.50 h, showed a high conversion of precursor iron oxides into hematite, with percentages of this phase ranging between 86.4 and 94.6%. The highest hematite obtaining was achieved at a condition of 850 °C and 1.00 h.   https://revistas.uis.edu.co/index.php/revistauisingenierias/article/view/10168ɑ-Fe2O3iron oxidepigment characterizationcalcinationcrystalline phases
collection DOAJ
language English
format Article
sources DOAJ
author María Angélica Colpas-Ruiz
Camilo Gnecco-Molina
José Pérez-Mendoza
Oscar Higuera-Cobos
Gabriel Jiménez-Rodríguez
spellingShingle María Angélica Colpas-Ruiz
Camilo Gnecco-Molina
José Pérez-Mendoza
Oscar Higuera-Cobos
Gabriel Jiménez-Rodríguez
Obtaining a hematite pigment by thermal transformation of the surface oxide of reinforcing steel bars
Revista UIS Ingenierías
ɑ-Fe2O3
iron oxide
pigment characterization
calcination
crystalline phases
author_facet María Angélica Colpas-Ruiz
Camilo Gnecco-Molina
José Pérez-Mendoza
Oscar Higuera-Cobos
Gabriel Jiménez-Rodríguez
author_sort María Angélica Colpas-Ruiz
title Obtaining a hematite pigment by thermal transformation of the surface oxide of reinforcing steel bars
title_short Obtaining a hematite pigment by thermal transformation of the surface oxide of reinforcing steel bars
title_full Obtaining a hematite pigment by thermal transformation of the surface oxide of reinforcing steel bars
title_fullStr Obtaining a hematite pigment by thermal transformation of the surface oxide of reinforcing steel bars
title_full_unstemmed Obtaining a hematite pigment by thermal transformation of the surface oxide of reinforcing steel bars
title_sort obtaining a hematite pigment by thermal transformation of the surface oxide of reinforcing steel bars
publisher Universidad Industrial de Santander
series Revista UIS Ingenierías
issn 1657-4583
2145-8456
publishDate 2020-05-01
description In this investigation work, the valuation of the surface oxide waste from reinforcing steel bars through to its thermal transformation into a pigment composed mainly of hematite (ɑ-Fe2O3) is reported. X-ray Fluorescence (XRF) and X-ray Diffraction (XRD) were used to determine the elemental content of the processed waste and identify the iron oxides involved in the calcination, respectively. The steelmaking waste powder is mainly composed by Fe2O3 (87.92 %), SiO2 (6.13 %), CaO (1.88 %), Al2O3 (1.30 %) and MnO (0.77 %). The total iron content corresponds to the following iron oxides: magnetite, maghemite, wustite, lepidocrocite, hematite and goethite. The thermal treatment of the residue at temperatures of 750-850 °C and holding times of 0.5-1.50 h, showed a high conversion of precursor iron oxides into hematite, with percentages of this phase ranging between 86.4 and 94.6%. The highest hematite obtaining was achieved at a condition of 850 °C and 1.00 h.  
topic ɑ-Fe2O3
iron oxide
pigment characterization
calcination
crystalline phases
url https://revistas.uis.edu.co/index.php/revistauisingenierias/article/view/10168
work_keys_str_mv AT mariaangelicacolpasruiz obtainingahematitepigmentbythermaltransformationofthesurfaceoxideofreinforcingsteelbars
AT camilogneccomolina obtainingahematitepigmentbythermaltransformationofthesurfaceoxideofreinforcingsteelbars
AT joseperezmendoza obtainingahematitepigmentbythermaltransformationofthesurfaceoxideofreinforcingsteelbars
AT oscarhigueracobos obtainingahematitepigmentbythermaltransformationofthesurfaceoxideofreinforcingsteelbars
AT gabrieljimenezrodriguez obtainingahematitepigmentbythermaltransformationofthesurfaceoxideofreinforcingsteelbars
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