search.noResults

search.searching

dataCollection.invalidEmail
note.createNoteMessage

search.noResults

search.searching

orderForm.title

orderForm.productCode
orderForm.description
orderForm.quantity
orderForm.itemPrice
orderForm.price
orderForm.totalPrice
orderForm.deliveryDetails.billingAddress
orderForm.deliveryDetails.deliveryAddress
orderForm.noItems
SAFETY IN THE PLANT


Magnetic Disc Separator Processes Beach Sands


Bunting’s latest Magnetic Disc Separator (MDS) is for processing and separating key minerals from a beach sands deposit. The three-stage Magnetic Disc Separator is destined for a mineral processing operation in Africa.


Bunting is one of the world’s leading designers and manufacturers of magnetic separators for the mineral processing, mining and ceramic industries. The Bunting European manufacturing facilities are in Redditch, just outside Birmingham, and Berkhamsted, both in the United Kingdom.


In this latest project, the beach sands mineral mix includes ilmenite, garnet, monazite, silica sand, rutile, and zircon. Prior to determining the specification of the production-scale Magnetic Disc Separator, Bunting undertook comprehensive material tests in their mineral processing laboratory at Redditch. The controlled tests determined the magnetic power required at each stage to produce a successful separation.


The production-scale Magnetic Disc Separator has six distinct separation stages. In operation, the beach sands mineral mix is evenly fed via a vibratory feeder onto a conveyor belt which passes under all three magnetic discs. Each magnetic disc produces a different magnetic force to separate a specific group of minerals. In addition, each magnetic disc is positioned at a tilt of approximately 1 to 2mm to generate two slightly different magnetic fields at the front and rear of each disc. Subsequently, there are six separate stages of separation.


Magnetic Disc Separator set up for final product tests


Magnetic Disc Separators (MDS) enable an accurate separation of minerals with varied magnetic susceptibilities. Typically, a Magnetic Disc Separator will feature up to three high-intensity electromagnetic discs, each set at a different height from a feed conveyor. The first disc will be set the furthest from the feed material, in order to extract only the most magnetically susceptible particles. The second and third discs are set at lower gaps, increasing the magnetic force at each disc and therefore separating different grades of magnetic material. Magnetic intensity can also be further adjusted by varying the current of each coil to suit each client’s specific mineral separation requirements.


Unlike other designs, Bunting have a designated coil for each magnetic disc. The coil and magnetic disc relationship enable precise adjustment of the magnetic field at each stage and ensures accurate generation of the optimum magnetic field.


MARCH/APRIL 2020


In this beach sands application, disc 1 is set to first produce 7000 gauss on the surface the belt (separation stage 1) and 8000 gauss at the rear (separation stage 2). The mineral mix is conveyed under the clockwise rotating disc with the 7000 gauss magnetic field removing larger iron-bearing particles including the highly paramagnetic ilmenite (FeTiO3


)


into the first collection area to the left of the feed direction. The black mineral rich fraction is used as a source for TiO2


The magnetic field strength at the rear of the disc is 8000 gauss and removes any remaining and smaller-sized particles of ilmenite. The combined ilmenite recovery rate from disc 1 is +95%.


Disc 2 is rotating in a counter-clockwise direction to the conveyor feed and focuses on recovering minerals of medium magnetic susceptibility. Separation stage 3 uses a magnetic field of 13,000 gauss to recover pink and red minerals such as Almandine Garnet (Fe3


disc is generating a higher field of 14,000 gauss. This recovers any remaining almandine garnet. In this


Al2 SiO2 www.reviewonline.uk.com ). At the rear, the magnetic .


application, the recovered garnet is sized for use as an abrasive grit media in shot-blasting applications.


6 recovering smaller monazite particles. Through the two separation stages recovery is +95%. Monazite is a phosphate mineral that contains rare earth elements; in this case the minerals include Neodymium, Cerium, Lanthanum and Praseodymium. The mineral is a highly valued raw material source for rare earth magnet manufacture.


The third and final magnetic disc rotates in a clockwise direction in relationship to the feed and is set to produce fields of 16,000 (separation stage 5) and 22,000 (separation stage 6). Separation stage 5 is for the recovery of the weakly paramagnetic orange-brown mineral monazite ((Ce,La,Nd,Th)PO4


) with stage


One of the 3 magnetic discs across the conveyed mineral mix


The remaining non-magnetic, cream- coloured mineral fraction is a mix of silica sand, rutile and zircon sand, which is separated using electrostatics, froth flotation and density separation. Rutile is used in the production of tioxide (via the Chloride route); zircon sand is commonly used in ceramics; and silica sand is the base material in the manufacturing of glass and ceramics.


The ability of the Magnetic Disc Separator to produce six different fractions from one source makes the technology ideal and unique for many applications. Presently, Bunting is manufacturing a number of Magnetic Disc Separators every year as well as undertaking numerous tests in their mineral processing laboratory.


The Magnetic Disc Separator is one of several specialist high-intensity magnetic separators in Bunting’s mineral processing portfolio.


For more information please contact: press@buntingeurope.com www.mastermagnets.com


Enquiry No. 35


35


Page 1  |  Page 2  |  Page 3  |  Page 4  |  Page 5  |  Page 6  |  Page 7  |  Page 8  |  Page 9  |  Page 10  |  Page 11  |  Page 12  |  Page 13  |  Page 14  |  Page 15  |  Page 16  |  Page 17  |  Page 18  |  Page 19  |  Page 20  |  Page 21  |  Page 22  |  Page 23  |  Page 24  |  Page 25  |  Page 26  |  Page 27  |  Page 28  |  Page 29  |  Page 30  |  Page 31  |  Page 32  |  Page 33  |  Page 34  |  Page 35  |  Page 36  |  Page 37  |  Page 38  |  Page 39  |  Page 40