DE102005032661A1 - Cleaning magnetic separator, for removing magnetizable impurities from non-metallic particles, especially crushed quartz glass for recycling, using suction unit with slit nozzle located after magnetic zone - Google Patents

Abstract

Apparatus for cleaning a magnetic separator (1), for removing magnetizable particle impurities (4b) from non-metallic particulate material (4), comprising a continuously moving endless conveyor belt support continuously supplied with the starting material and passing through a magnetic separation zone, consists of a suction unit (6) with at least one slit nozzle (9), located after the magnetic zone at a short distance from the support and transverse to the direction of motion and operatively connected to the separator : An independent claim is included for a method for reprocessing recycled quartz glass as starting material for production of sintered amorphous silica ceramic products, involves: (a) crushing the glass to the required particles size in milling apparatus; (b) applying the crushed product to a magnetic separator, provided with a cleaning device, as above; and (c) collecting the granular product, free of magnetizable metallic impurities, for further use.

Description

The The invention relates to a device for cleaning a Magnetic separator for with magnetizable particles contaminated non-metallic bulk, which has a continuously moving endless transport support, the continuous with the bulk material is charged and this at a magnetic zone for deposition the magnetizable particle passes.

The The invention further relates to a method for reprocessing of quartz glass with such a device.

Products made of a ceramic or glassy material are today increasingly recycled, ie recycled for the production of products made of a ceramic or glassy material. Such reclamation typically takes place in a glassmaking operation, whether to provide shards as an additive to the molten glass or to provide granular, free-flowing solid, ie, bulk, for the production of amorphous SiO ₂ ceramic products Processes, ie of products, for example, under the brand QUARZAL ^® on the market.

The Processing of the aforesaid to recycled ceramic products and glassy materials requires a mechanical comminution of these products by means of appropriate grinding tools, such as jaws or roll crusher.

at This preparation, in particular the coarse crushing of hard Ceramic and glassy raw materials are subject to very high abrasion on all metallic components in the processing plant. Most affected are the grinding tools, i. the jaw or roll crushers. In the case of quartz glass to be processed, during the Processing process - in dependence from initial geometry of raw material - the crushed grain with accumulate up to 5% by mass of metallic abrasion. For the most Applications, such a high metal content is unacceptable, so that magnetic separator integrated into the treatment process Need to become.

there be for Bulk goods with a particle size between 10 mm and 0.1 mm usually used drum magnetic separator. Such drum magnetic separators have become known in various embodiments, with reference to the German patent specification 1 189 031 referenced becomes.

The principle of operation of such drum magnetic separator is as follows:
The drum magnet consists of a magnetic and a non-magnetic part. Both parts are surrounded by a rotating drum. The bulk material to be cleaned is guided past this drum. There are different principles: For example, the drum is guided either in the material flow direction or contrary to the material flow direction of the material to be cleaned over. In this process, the magnetizable particles of the bulk material remain due to the action of the magnet adhere to the drum surface, while the non-magnetic material passes unhindered past the rotating drum. The adhesive, magnetizable particles only fall off the drum when they have left the magnetic zone. Different magnet systems such as permanent magnets or electromagnets are used. By this system basically very good separation results can be achieved.

A Certain problems are, however, given insofar that only in the ideal case, all adhering metal particles outside Detach the magnetic zone from the rotating drum. In practice it turns out that smallest particles despite the transition to the nonmagnetic Part on the drum surface stick to it. In the operation of the plant thus builds up in the aftermath an increasingly thick metallic coating. This reduces the attraction of the magnetic field, causing the deposition performance decreases considerably. additionally there is a risk that metallic particles will no longer remain until the non-magnetic part to be transported, but intermittently metal particles fall into the regular bulk, which in this concentrated form can lead to considerable production disruptions.

Around To address this problem, for example, as the aforementioned DE-document 1 189 031 shows scrapers in the form of a scraper blade used. But also wipers, such. Brushes and squeegee, be used. The disadvantage of this cleaning method is the high wear of the scrapers and wipers, as well as the low efficiency, since smallest particles stick nevertheless. Another technical solution is it, in the non-magnetic region, a magnet with reversed polarity use. Also in this case, the experience shows that smallest Particles remain attached. Nevertheless, a good separation result too It is therefore essential in practice to interrupt the process and to clean the drum by hand. Experience shows that this is necessary on average every two hours. There is thus so far no suitable system for cleaning drum magnetic separators in operation.

The same problem is with other magnetic separators, such as magnetic tape separators or flat bed separators according to the DE 32 18 791 A1 in which spaced from each other tubes are provided with bar magnet alternating polarity, given, with respect to the flat bed separator according to the aforementioned DE-font on each tube serving as a scraper slider is mounted axially displaceable, with the same disadvantages, as in connection with the Drum magnetic separators has been described above.

Of the Invention is based on the object, the initially designated device for cleaning magnetic separators in such a way that a high efficient, virtually residue-free Cleaning during operation of the separator is possible.

The solution This object is achieved with a device for cleaning a Magnetic separator for with magnetizable particles contaminated non-metallic bulk, which has a continuously moving endless transport base, the continuously with the bulk material is charged and this at a magnetic zone for depositing the passes magnetizable particles, according to the invention in that the magnetic separator, a suction unit with at least one slot nozzle, the behind the magnetic zone at a short distance from the surface is arranged transversely to the direction of movement, assigned and operational coupled with it.

By the measures according to the invention a cleaning system has been created, which is the continuous Operation of the separator system not hindered. Located on the endless transport base of the separator accumulating, metallic coating from not selbstätig falling by gravity Metallic abrasion particles becomes non-contact and through the operational Coupled with the separator continuously sucked from the surface and environmentally friendly fed to a dedusting system. A manual cleaning the pad is omitted in interrupted operation of the separator because the metallic coating can be almost completely sucked off.

further developments and embodiments of the invention are characterized in dependent claims and also result from the description of the figures.

Based an embodiment described in the drawing, the invention described in more detail.

It demonstrate:

1 in a schematic representation of a drum magnetic separator for bulk materials with magnetizable metallic impurities in conjunction with a high-performance suction unit for sucking adhered to the drum metallic coating, and

2 in an isometric view of the closer structure of the central component of the suction unit, the compressed air suction and delivery nozzle.

The 1 shows a drum magnetic separator 1 with a rotating drum 2 , in the middle of which there is a magnet 3 is mounted stationary, which is preferably formed by a permanent magnet. The bulk material to be cleaned 4 , with relatively large-particle particles 4a made of processed material, in particular a glassy material, and relatively small particles 4b a metallic abrasion from the grinding units, which are typically magnetizable, are on a vibrating trough 5 abandoned, from where they on the rotating drum magnetic separator 1 reach. The processed particles 4a fall from the drum after a predetermined angle of rotation due to gravity 2 and are collected in an associated container, whereas the magnetized abrasive particles 4b initially still on the drum 2 and only fall off when they have left the magnetic zone. Some abrasive particles 4b However, they still adhere to the drum surface as an impurity and gradually form a coating, which by the high-performance suction unit according to the invention 6 removed after a while.

This high-performance suction unit has as a central component a compressed air suction and delivery nozzle 7 that also in the 2 is shown in more detail on. This compressed air suction and delivery nozzle 7 contains a basic body 8th , the suction side with a slot nozzle 9 is connected and the output side an axially adjustable screw 10 has, which is connectable to a dedusting system. By means of a lock ring 11 the axial position of the screw can be fixed.

The compressed air suction and delivery nozzle 7 also has a connection piece 12 on, at which by means of a dog clutch 13 a compressed air source can be connected. Power and compressed air consumption are of the axial position of the screw 10 dependent. At the connection piece 12 is also a ball valve 14 attached, over which the power of the delivery nozzle can be adjusted independently of the setting of the screw.

To the compressed air suction and delivery nozzle 7 is also a time control 15 connected by which the high performance suction unit 6 switched on and off at predetermined time intervals, ie at appropriate intervals a negative pressure at the slot nozzle 9 can be generated, which completely removes the metallic coating from the drum and the dedusting system feeds.

The slot nozzle 9 it typically has a slot width of about 1 mm and its distance to the drum surface is also about 1 mm. The slot of the nozzle expediently extends over the entire drum width, with designs with several offset over the drum width parallel nozzles are conceivable.

For very high demands on the purity of the processed material and slot nozzles can be connected in series, the alternating or parallel to the compressed air suction and delivery nozzle 7 be turned on.

there Also, a double slot nozzle, i. a nozzle with two consecutive slots are provided.

By the system according to the invention permanently ensures a clean and therefore efficient drum surface and a re-cleaning of the drum by hand is not necessary. The System is wear-free and can be on the fly, without any disruption to production cause to be used. The implementation is easy and cheap. By This system can be almost 100% of the registered magnetizable Abriebs be removed from the processed bulk material, i. that, for example, the Fe content after comminution of the Starting material corresponds, e.g. 3.45 ppm at a high quality Quartz glass raw material or 12.5 ppm for a less high-quality quartz glass raw material.

Embodiment:

When Starting material was a lumpy quartz glass (Diameter up to 200 mm) in a grinding unit with one jaw each and roll crushers crushed. The crushed particles and the Metallic abrasion was a drum magnetic separator with a Roller width of 35 cm and supplied with a permanent magnet of neodymium. When High performance suction unit became a compressed air suction and delivery nozzle DDS 60 the company Keller Lufttechnik GmbH & Co. KG, New Weilheimerstraße 30, 73230 Kirchheim unter Teck used, which activates every 3 min for 2 min has been. The metallic coating was completely removed from the drum, so no manual re-cleaning was necessary.

• – von 1–2 mm: 250 kg/h
• – von 0,3–1 mm: 175 kg/h.

The processing power was for grains

• - from 1-2 mm: 250 kg / h
• - from 0.3-1 mm: 175 kg / h.

Is appropriate the entire treatment plant made of magnetisable materials built, which makes the complete Removing an abrasion over the magnetic separator is ensured.

The High performance suction unit according to the invention is also for the application with magnetic tape separators suitable.

• – Zerkleinern des Quarzglases in Mahlwerkzeugen auf die erforderliche Korngröße
• – Aufbringen des zerkleinerten Quarzglases auf eine kontinuierlich bewegte Endlos-Transportunterlage eines Magnetabscheiders, dem eine Saug-Einheit mit mindestens einer Schlitzdüse, die hinter der magnetischen Zone im kurzen Abstand von der Unterlage quer zu deren Bewegungsrichtung angeordnet ist, zugeordnet und betrieblich mit ihm gekoppelt ist, und
• – Sammeln des von magnetisierbaren metallischen Verunreinigungen befreiten körnigen Quarzglases für dessen weiteren Verwendung.

The invention further relates, as mentioned above, also to a process for reprocessing recycled quartz glass as a raw material for the production of amorphous SiO ₂ sintered products by ceramic processes, with the following steps:

• - Crushing the quartz glass in grinding tools to the required particle size
• - applying the comminuted quartz glass to a continuous moving endless transport support of a magnetic separator, which is associated with and operatively coupled to a suction unit having at least one slit nozzle disposed behind the magnetic zone at a short distance from the support transverse to its direction of movement , and
• - Collecting the freed from magnetizable metallic impurities granular silica glass for its further use.

With this method, a high-purity silica glass precursor for the production of leaves for ceramic process produced amorphous SiO ₂ -products, as are known for example under the brand name Quarzal ^® provide.

1

Drum magnetic separator

2

drum

3

magnet

4

bulk

4a

large particle size made of recycled material

4b

Abrasion particles

5

vibrating

6

High performance suction unit

7

Druckluftsaug- and delivery nozzle

8th

body

9

slot

10

screw-in

11

lock ring

12

connecting branch

13

claw clutch

14

ball valve

15

timing

Claims (13)

Device for cleaning a magnetic separator for magnetisable particles ( 4b ) contaminated non-metallic bulk material ( 4 ), which has a continuously moving endless transport support ( 2 ), which continuously with the bulk material ( 4 ) and this at a magnetic zone for separating the magnetizable particles ( 4b ), characterized in that the magnetic separator ( 1 ) a suction unit ( 6 ) with at least one slot nozzle ( 9 ) located behind the magnetic zone at a short distance from the substrate transverse to its movement means, associated and operationally coupled thereto. Device according to claim 1, characterized in that the suction power of the suction unit ( 6 ) is adjustable. Device according to claim 1 or 2, characterized in that the suction unit ( 6 ) a time control ( 15 ) is assigned to activate the suction unit for predetermined time intervals during the current deposition process. Device according to one of claims 1 to 3, characterized in that the suction unit ( 6 ) by a compressed air suction and delivery nozzle ( 7 ), on the suction side the slot nozzle ( 9 ) is mounted and the conveyor side is connectable to a dedusting system is formed. Device according to claim 2 and 4, characterized in that the compressed air suction and delivery nozzle ( 7 ) on the delivery side an axially displaceable screw-in part ( 10 ) for adjusting the suction power. Device according to claim 5, characterized in that a lock ring ( 11 ) for releasing and fixing the screw-in part ( 10 ) is provided. Device according to one of claims 4 to 6, characterized in that the compressed air suction and delivery nozzle ( 7 ) a connecting piece ( 12 ) with a ball valve ( 14 ) for connection to a compressed air source. Device according to one of claims 1 to 7, characterized in that the slot width of the slot nozzle ( 9 ) is in the range of 1 mm. Device according to one of claims 1 to 8, characterized in that the distance of the slot nozzle ( 9 ) from the transport document ( 2 ) is in the range of 1 mm. Device according to one of claims 1 to 9, characterized in that the longitudinal extent of the slot nozzle ( 9 ) corresponds to the width of the transport support. Device according to one of claims 1 to 10, characterized that the slot nozzle through a double slot nozzle with two in the conveying direction the separator formed successively slits is. Device according to one of claims 1 to 11 with a magnetic separator for bulk material ( 4 ), which is recycled by means of upstream grinding tools, characterized in that the grinding tools are constructed of magnetizable materials. A method for reprocessing recycled quartz glass as a raw material for the production of amorphous SiO ₂ sintered products by ceramic processes, comprising the steps of: - crushing the quartz glass in grinding tools to the required grain size - applying the comminuted quartz glass to a continuously moving endless transport base of a Magnetic separator, the suction unit with at least one slot nozzle, which is located behind the magnetic zone at a short distance from the substrate transversely to the direction of movement associated with and operatively coupled thereto, and - collecting the freed from magnetizable metallic impurities granular silica glass for its further use.