DD261106A1 - MATRIX FOR MAGNETIC SEPARATOR - Google Patents

Abstract

The invention relates to a matrix for magnetic separators for the separation of paramagnetic constituents and ferromagnetic and ferromagnetic admixtures of Koernerhaufwerken in wet and dry work, whereby the magnetic blocking of the induction prevents body and the investment and operating costs is reduced. According to the invention, low-corrosion, preferably corrosion-free, soft magnetic plates are arranged parallel and at a distance from each other and perpendicular to the magnetic field of the separator used as matrix elements, so that the magnetic interaction force of the plates with chains of magnetized particles is not reduced by corrosion layers and no external magnetic field gradients can arise. The soft magnetic plates are maintained at a distance by non-magnetic spacers, which depends on the bulk of the feed material and the susceptibilities of its magnetic components, and connected by non-magnetic fasteners.

Description

For this 1 page drawing

Field of application of the invention

The invention relates to a matrix for magnetic separators for the separation of paramagnetic components and ferromagnetic and ferromagnetic admixtures of grain heaps in wet and dry work.

Characteristic of the known technical solutions

There are matrices for magnetic separators for the separation of paramagnetic components such as hematite, ilmenite, wolframite, biotite, limonite, siderite, etc. from grain heaps known. Such matrices are in the known Induktionskörpermagnetscheidern of various designs (Jones-Magnetscheider, Humboldt-Wedag, DE-AS 1132062; Processing Technology (1973) 3, pp 142-149 / supplement; HIW Magnetic Seperator England, company pressure Boxmag-Rapid BR 18, SALA HGMS Series 480 Carousel USA, SALA-International SALA-HGMS Series 185 Carousel USA, SALA Magnetic, HGMS by Zelezorudne bane Spisskä Nova Ves, CSSR, Hornickä Pribram ve vede a technice, Symposium 18.- 22.10.1982) in the form of highly magnetizable grooved plates, profiled wires, expanded metal, steel wool, spheres, rods, etc. used.

All these matrices have in common that they have induction bodies of any geometric shape with strong curvatures of the surfaces and therefore generate high magnetic fields in external magnetic fields, which in turn lead to high magnetic forces on particles in the environment.

The principle of operation of these matrices in magnetic separation is based on introducing a cloud of suitable solids concentration between their induction bodies in the presence of a strong magnetic field. Due to the magnetic field and the high field gradients on the induction bodies, the more paramagnetic, ferromagnetic and ferromagnetic components of the turbidities are deposited, while weaker paramagnetic and diamagnetic components flow freely. The adhering to the induction magnetic particles are first washed in the magnetic field, whereby an intermediate product is discharged, and rinsed after washing without magnetic field with rinsing fluid under high pressure.

Ferro- and ferrimagnetische admixtures in the pulp as Abriebeisen or magnetite adhere even without magnetic field sometimes so strong on the induction bodies that even high water pressure is not sufficient to flush them out. This is caused in particular by the remanence in conjunction with the strong curvatures on the surface of the induction body, because the residual magnetic field and the field gradient and thus also the residual magnetic force on the ferromagnetic and ferrimagnetic admixtures are unacceptably high. The consequence is that the induction bodies must crust and cleaned or prematurely replaced, otherwise the matrix is magnetically blocked. Both measures require working time and cause significant costs, so that in addition Induktionskörpermagnetscheidern in addition weak field magnetic separator for separating ferro- and ferrimagnetischer admixtures upstream. Although the expense of setting up and operating these additional aggregates is high, they do not provide a solution to the problem because the low-field separators deposit only a portion of the highly magnetic impurities of the feed material and therefore merely delay the magnetic blocking of the matrix. Another disadvantage is the large space requirement and the need for multiple separation stages. In one case (DDR PS 202 632S) matrices of non-magnetic separating bodies in the form of mutually parallel and perpendicular to the field arranged rods or plates have been proposed; The non-magnetic separators can also be formed by structures of wires or bulk solids. If a feed material is added to such a matrix in the magnetic field, its more magnetizable constituents are retained in the field direction as chains of polarized particles between the appropriately spaced nonmagnetic separators, while weakly paramagnetic and diamagnetic constituents flow freely out of the matrix. After leaving or switching off the magnetic field, the polarization particle chains of paramagnetic particles disintegrate even if they are contaminated by strongly magnetic particles and can easily be rinsed out. The disadvantage here is that the type of deposition is limited only to sludge, since the weak adhesive forces between the non-magnetic separating bodies and the polarization chains these only withhold if they have a low mass, d. h., if their particles are very small.

For example, in a matrix of parallel aluminum plates spaced 1 mm apart, an induction of 1.2T hematite particles <10μηη can be separated from a slurry. Another disadvantage is that the deposition of paramagnetic and ferromagnetic components is only possible if they exceed a certain minimum content in the task, otherwise no polarization particle chains can form. A shortcoming is also that compared to certain Induktionskörpermatrizen (eg grooved plate, expanded metal or Kugelmatrizen) for equal induction between the non-magnetic separation bodies by about ¹ A higher flooding is required, which due to their space requirement not through higher throughput than in comparable Induktionskörpermatrizen is compensated. The higher flooding requirement requires higher costs for increased electrical current and / or higher investment costs for windings with larger numbers of turns in the separator used.

Object of the invention

The aim of the invention is to prevent magnetic separation of the Jnduktionskörper by ferri and ferromagnetic components of the feed material in the magnetic separation with Starkfeldmagnetscheidern and to reduce the cost of investment and operating costs.

Explanation of the essence of the invention

The invention has for its object to ensure by appropriate design of the matrix, the deposition of paramagnetic, ferromagnetic and ferromagnetic components of the feed material and largely eliminate the effect remanenzbedingter residual magnetic forces outside the magnetic field on the separated ferromagnetic and ferrimagnetic particles, limiting the deposition to avoid sludge and levels of magnetic component above a certain minimum content and to prevent increased flooding demand. This object is achieved in that in the matrix low-corrosion, preferably corrosion-free, smooth on the surface, soft magnetic plates (1) are arranged parallel and spaced from each other and perpendicular to the magnetic field of the separator used as matrix elements, so that the magnetic interaction force of the plates (1) with chains of magnetized particles is not reduced by corrosion layers and no external magnetic field gradients can arise. It is characteristic that the distance of the soft magnetic plates (1) by non-magnetic spacers (2) is determined to prevent a partial magnetic short circuit between the plates (1). Further, it is characteristic that the soft magnetic plates (1) are connected via the nonmagnetic spacer elements (2) and the connecting elements (3) are also nonmagnetic in order to prevent a partial magnetic short circuit between the plates (1). If the matrix is brought into the approximately homogeneous magnetic field of an induction body magnetic separator, magnetic field gradients do not develop due to the soft magnetic plates (1) oriented perpendicular to the field and smooth on the surface, but the field homogeneity is improved. If the material to be separated is added to the matrix as turbid or dry granules, stronger paramagnetic and ferromagnetic and ferrimagnetic components are retained between the soft magnetic plates (1) as chains of polarized particles with sufficient strength of the nearly homogeneous magnetic field by magnetic interparticle interaction forces. The weaker paramagnetic and diamagnetic constituents flow out of the matrix and are collected as a non-magnetic product, the deciding forces between the soft magnetic plates (1) and the ends of the polarization particle chains being determined by the magnetic dipole forces between them and the plates (1) This eliminates the restriction of deposition to sludge. Likewise, the restriction to contents is greater than a certain minimum content avoided at magnetic component, since the Dipolbildkräfte also hold individual grains on the soft magnetic plates. The soft magnetic plates (1) prevent in the magnetic field that compared to known induction body matrices, for example, groove plates, expanded metal or spheres, an increased flooding demand occurs. Subsequently, the magnetic material held in the matrix is cleaned by washing liquid or compressed air in the magnetic field, thereby collecting an intermediate product under the matrix. Without an external magnetic field, the polarization particle chains then decay. In the remanent magnetic field of the soft magnetic plates (1), the gradient generated by only the magnetized particles and thus the interparticular Weckseiwirkungskräfte and the Dipolbildkräfte are so small that they no longer stabilize the polarization particle chains or between the plates (1) can hold. Due to the smooth, plate-shaped Iriduktionskörper outer field gradients are also avoided, so that when rinsing without magnetic field and ferromagnetic and ferrimagnetic particles are not retained in the matrix. The magnetic product is completely discharged by rinsing liquid or compressed air.

The invention will be explained in more detail with reference to an embodiment and a drawing. The figure shows the structure of a matrix of soft magnetic plates.

embodiment

The matrix is composed of soft magnetic plates 1, which consist of a suitable corrosion-resistant chromium steel sheet. The distance between the plates 1 is held by perforated discs 2 made of aluminum. As connecting elements 3 of the matrix are bars made of aluminum, which protrude through corresponding holes in the plates 1 and through the perforated discs 2 and are riveted at both ends. The outer dimensions of the matrix are chosen so that it fits in perpendicular to the magnetic field oriented plates 1 in the work boxes of the rotor or canister-Induktionskörpermagnetscheiders used. The matrix height is at least 15-20cm. The distance of the soft magnetic plates is adapted to the grain size and the susceptibility of the feed material to be processed. It is about 1mm for fine grains.

The matrix is exposed to the approximately homogeneous magnetic field in the work box of a rotor or canister-Induktionskörpermagnetscheiders and supplied the feed material as cloudy or dry grain. With sufficient magnetic induction stronger paramagnetic, ferromagnetic and ferromagnetic constituents of the feed material are deposited between the magnetic magnetic plates 1 perpendicular to the magnetic field as chains of polarized particles, while weak paramagnetic and diamagnetic components flow out of the matrix unaffected and discharged as a non-magnetic product. By washing with a washing liquid or with compressed air, the deposited magnetic components are cleaned while an intermediate product is discharged. Without magnetic field break the polarization particle chains or lose their stability and are discharged by rinsing liquid or compressed air as a magnetic product.

In contrast to the known matrices with strongly curved surfaces, the matrix according to the invention is suitable for eliminating more paramagnetic constituents without first having to separate ferromagnetic and ferromagnetic admixtures of the feed material on weak field separators, since the polarization particle chains in which the magnetic product is held are decay in remanence magnetization of the soft magnetic plates 1 and lose their stability and therefore be completely discharged by flushing liquid or compressed air. The high costs and labor for cleaning or premature replacement and the consequent loss of availability omitted. Furthermore, as opposed to another known proposal, there is no restriction on the separation of sludges and heaps with magnetic component contents above a certain minimum content and the cost of increased flooding due to the use of non-magnetic separators. The matrix consisting of corrosion-free, smooth, soft magnetic plates is simpler, less time-consuming and cheaper to produce than matrices made of grooved plates, profiled wires, steel wool, rods, etc.

Claims (2)

1. matrix for magnetic separators for the separation of paramagnetic constituents from Körnerhaufwerken in wet and dry work while avoiding the magnetic blocking due to ferromagnetic and ferromagnetic admixtures, characterized in that low-corrosion, preferably corrosion-free, smooth on the surface, soft magnetic plates (1) parallel and Spacing between each other and perpendicular to the magnetic field of the separator used are arranged as matrix elements, so that the magnetic interaction force of the plates (T) with chains of magnetized particles is not reduced by corrosion layers and no external magnetic field gradients can arise. 2. matrix according to item 1, characterized in that the soft magnetic plates (1) by non-magnetic spacer elements (2) are kept at a distance and are connected by non-magnetic connecting elements (3).