REPLACEMENT OF CALCIUM FLUORIDE WITH BORATES AS CATALYST IN A VERTICAL RETORT PIDGEON PROCESS TO PRODUCE MAGNESIUM (A REVIEW)
The production of magnesium has been dominated by China. Chinese magnesium is produced by the silicothermic Pidgeon process. In the Pidgeon process, calcined dolomite, ferrosilicon as reductant, and calcium fluoride (CaF2) as a catalyst are charged into a vacuum horizontal retort. The retort is t...
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| Format: | Final Project |
| Language: | Indonesia |
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| Online Access: | https://digilib.itb.ac.id/gdl/view/51452 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The production of magnesium has been dominated by China. Chinese magnesium
is produced by the silicothermic Pidgeon process. In the Pidgeon process, calcined
dolomite, ferrosilicon as reductant, and calcium fluoride (CaF2) as a catalyst are
charged into a vacuum horizontal retort. The retort is then heated externally to
reduce the charged briquette. The Pidgeon process is characterized by its low
capacity, relatively simple technology, batch process, low capital expenditure, and
large emission of carbon dioxide from the calcination and reduction process. The
low capacity is caused by the slow heat transfer rate from external heating, limiting
the retort size. The slag has a small particle size that leads to dust formation. Due
to the use of calcium fluoride, the slag also contains fluorine that its concentration
is above the acceptable limit. Vertical retorts for the Pidgeon process can allow
larger retort diameters. Borates such as B2O3 have been used to treat other fine
metallurgical slags such as AOD slag from stainless steel production. This work
aims to study the available vertical retort designs and examine the approach taken
by each design to improve the Pidgeon process, and to study the effects caused by
the replacement of CaF2 with borates as a catalyst for the Pidgeon process.
This study starts with the collection of existing works and publications concerning
the Pidgeon process. After that, collected works will be sorted and selected based
on their relevance to this work. Then, the selected documents will be reviewed and
analyzed to fulfill the objectives of this study. The reviewed documents and the
phenomenon observed in each work will be compared to one another. If there exists
some gap in the explanations provided by previous works, further search and review
of references are suggested. Finally, conclusions are drawn from the review.
Based on the conducted literature review, the following conclusions can be drawn:
1) Vertical retort designs for Pidgeon process have existed in at least a pilot-plant
level application. However, there is a distinct lack of data needed to evaluate the
relative performance of each design. 2) Vertical retort designs have the potential for
space-saving, automation, and has a greater degree of reduction progress
monitoring. 3) Full replacement of CaF2 with H3BO3 is not suggested, but a partial
replacement is feasible. Partial replacement reduces fluorine content in magnesium
slag and increased the particle size of magnesium slag. Calcium fluoride and borates
seem to speed up reduction by forming a liquid slag phase that improves reactant
transport. Several suggestions are made: 1) to experiment with lab-scale vertical
Pidgeon process retort to gain first-hand data that can be compared with lab-scale
horizontal retorts and 2) to investigate the cause of borates’ lower productivity
compared to CaF2 when used as the catalyst for Pidgeon process. |
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