AT391280B - MAGNETIC CUTTER II - Google Patents

Abstract

During the magnetization of many particles which can be magnetized to the same intensity or to some extent to different intensities, it is possible for chains to form as a result of deposition of the particles on one another, these chains essentially being aligned in the direction of the magnetic induction produced by the magnetic separator. The object of the invention is to provide a magnetic separator which avoids these disadvantages. According to the invention, this is achieved in that in the separation volume, the magnetic induction is approximately perpendicular to the gradient of the magnetic field. The exciter coils 3 and 5, which are arranged above the plane of symmetry 2, have current flowing through them, for example in the positive direction, the exciter coils 4 and 6, which are arranged underneath the plane of symmetry 2, accordingly likewise have current flowing through them in the positive direction. As a result of the equidirectional current flow arrangement, the magnetic flux between the coil pairs 3, 5 on one side and 4, 6 on the other side bulges out, so that a gradient in the magnetic field is produced, which is approximately perpendicular to the magnetic induction produced by the coils, and an approximately constant separation-force density is generated in the annular-channel-like separation volume 7. <IMAGE>

Description

No. 391 280

The invention relates to a magnetic separator, the magnetic field, which generates the force density in the separating volume that is necessary for the separation with high selectivity and is adapted to the counterforce, to a large extent induced by the shape and position of the energizing coils, according to patent no. 379 525.

The magnetic separators used industrially today are generally well suited to separating materials with ferromagnetic or strongly paramagnetic properties from other materials with diamagnetic or weakly paramagnetic properties. A separation of materials with only slight differences in their paramagnetic properties is only possible in some magnetic separators suitable for Lahnratorinnrisy.wer.kfi.

From US Pat. No. 2,056,426 on such a device it is known that a magnetic field is necessary for the extensive separation of materials with small differences in their paramagnetic properties, in which the forces on particles with a certain volume sensitivity X5 are independent of the location in the considered volume. To do this, there must be a balance between the magnetic force and an opposing counterforce on the particles. The magnetic force on a particle with the volume susceptibility X and the particle volume V is:

F = X. V. ΪΒΙ. degrees H -ft -ft. _ft

The field size f = IBI. degree H is a description of the magnetic field, it has the dimension of a force density (N / m ^) and is called the separation force density. In the ^ magnetic separator described in the aforementioned US patent, gravity is used as a counterforce, which is why it is required that the cutting force density f should be constant over the cutting volume. The magnetic field that meets these conditions is referred to in this document as an isodynamic magnetic field. Such a magnetic field is approximated by a specially shaped magnetic pole contour of an electromagnet with an iron yoke. If you want a different size as a counterforce, e.g. B. use the centrifugal force, the separation force density f must have the same spatial distribution as the counterforce.

In magnetic separators with magnetic flux guidance through an iron yoke, a corresponding contour of the iron yoke is necessary to form the necessary magnetic field. In such magnetic separators, the level of magnetic induction is essentially limited to the saturation induction of the iron yoke. In conjunction with a desired geometry of the volume in which the materials are to be separated, the greatest possible density of the cutting force is defined. If greater cutting force densities are necessary, the maximum magnetic induction must be increased if the geometry remains the same, or the geometric dimension must be reduced if the maximum induction remains the same.

An increase in the geometric dimension for the purpose of a larger throughput and / or the separation of larger grain classes requires an increase in the maximum induction if the density of the separation force is to remain unchanged. As a result, the iron yoke can no longer be used exclusively to form the magnetic field. The shape of the magnetic field is increasingly determined by the position and shape of the excitation coils as the strength of the magnetic induction increases. Increasing induction requires high ampere turns.

As already roughly outlined, a magnetic separation occurs when at least two forces act on magnetizable particles, at least one of which is caused by a magnetic field and is intended to move the particles in a certain direction, while the other forces as opposing forces or inertial forces do not cause the magnetic field affected particles should move in another direction or should remain in their original path or place.

AT-Patent No. 379 525 describes a magnetic separator which avoids the disadvantages of the above-mentioned magnetic fields and generates a magnetic field in which, for a certain volume sensitivity, the generated separating force is adapted to a corresponding counterforce, without being limited by the saturation induction of an iron yoke .

According to AT-PS No. 379 525, the magnetic field is induced by rotationally symmetrical coils, which are arranged symmetrically to the parting volume and flow through the opposite direction with respect to the plane of symmetry and which comprise the parting volume and the radius of the center of the parting volume is smaller than the largest radius of the excitation coils , but larger than the smallest radius of the excitation coils. This provides a simple solution to the problem of determining the geometry of the magnet coils.

This opposing current flow arrangement pushes the magnetic flux between the coils through which current flows in opposite directions. An approximately constant cutting force density is generated in the cutting volume, the magnetic field gradient degree H being approximately parallel to the magnetic induction B.

The magnetizable particles to be separated are generally magnetized approximately parallel to the magnetic induction B generated by the magnetic separator. Small deviations in the direction of magnetization from the magnetic induction B can result from the interaction of the particles involved with one another, but are only of minor importance.

When magnetizing a large number of particles that are magnetized to the same or different degrees, -2-

No. 391 280, chains can be formed by the attachment of the particles to one another, which are essentially oriented in the direction of the magnetic induction $ generated by the magnetic separator.

If a magnetic separator is built so that the magnetic field gradient degree H is approximately parallel to the magnetic induction S, the resulting chains will be approximately parallel to the magnetic field gradient S degree H, i. H. but are also approximately parallel to the separating direction of the separating force F. When the differently magnetized particles are separated, they must move along the chains or through the chains. The given position of these chains can make it difficult to separate the differently magnetized particles.

The object of the invention is therefore to provide a magnetic separator of the type mentioned at the outset which avoids the above-mentioned disadvantages

The magnetic separator according to the invention is characterized in that the magnetic induction in the separating volume is approximately perpendicular to the gradient of the magnetic field. This results in the possibility of separating particles of different strengths from attached chains, which are oriented approximately in the direction of magnetic induction B, more easily. 1S Furthermore, this provides a continuous possibility of cutting different paramagnetic materials, whereby the possible impairment of the selectivity due to chain formation in the separation direction is prevented.

According to a special embodiment of the invention, the magnetic field is induced by rotationally symmetrical coils, which are arranged symmetrically to the cutting volume and flow through in the same direction in relation to the plane of symmetry and include the cutting volume and the radius of the center of the cutting volume is smaller than the largest radius of the excitation coils, however larger than the smallest radius of the excitation coils. This provides a simple solution to the problem of determining the geometry of the magnet coils.

According to a development of the invention, the magnetic field is induced by elongated coils, the long sides of the coil being arranged symmetrically to a plane of symmetry and comprising the sheath volume arranged symmetrically to the plane of symmetry. These features relate to a separating channel arrangement in a geometry that is not rotationally symmetrical. For these conditions, the coil arrangement provides optimum constancy of the density of the cutting force.

According to a further embodiment of the invention, excitation coils made of metallic material such. B. copper, aluminum and. Like. Made. This version is sufficient for certain vaginal problems. Sie 30 is an economically viable solution.

According to a further feature of the invention, the excitation coils are made from superconductors. Weakly magnetic materials can only be separated using magnetic fields that can be generated from superconductors.

According to one embodiment of the invention, one or more iron cores or iron yokes are provided to increase the magnetic induction or to reduce the number of ampere turns. Likewise, one or more iron yokes or a normally conducting or a superconducting surface are provided for shielding the magnetic field. Likewise, one or more iron yokes or a normally conductive or a superconducting surface are provided to shield the magnetic field. The advantage of these two features is that the stray field is agreed and the useful field is increased. 40 In the drawing, the invention is explained in more detail using an exemplary embodiment. In the drawing, a rotationally symmetrical excitation coil arrangement is shown, with (1) the axis of rotation and (2) the plane of symmetry

The excitation coils (3) and (5), which are arranged above the plane of symmetry (2), are, for. B. flowed through in a positive sense, the excitation coils (4) and (6), which are arranged below the plane of symmetry (2), 45 are accordingly also flowed through in a positive sense. Due to the same-direction current flow arrangement, the magnetic flux between the coil pairs (3), (5) on the one hand and (4), (6) on the other hand bulges out, so that a gradient of the magnetic field arises which is approximately perpendicular to the magnetic generated by the coils Induction stands, and an approximately constant cutting force density is generated in the annular channel-shaped cutting volume (7). 50 In this example, the counterforce is the centrifugal force that acts on the particles moving at the transport speed in the annular channel-shaped partition volume (7). The superimposition of the centrifugal force with the drag forces in the carrier liquid, together with the small radial expansion of the parting volume, result in an approximately spatially constant counterforce, so that for particles of a certain volume sensitivity Xj by adjusting the flow velocity vq (hence the centrifugal force) and the 55 size the magnetic induction (hence the magnetic cutting force) can achieve a balance of forces regardless of the location within the cutting volume.

The magnetic separation force exerts a different force on the different material particles due to the different volume sensitivities of the materials to be separated. This magnetic force competes with the counterforce, which is approximately the same for all particles. For 60 material particles with greater volume sensitivity than Xj, the magnetic force predominates, while for

Material particles with a smaller volume sensitivity than Xj outweighs the opposing force. -3-

Claims (7)

No. 391 280 If the excitation coil arrangement is not considered as a rotationally symmetrical structure by the drawing, but rather as an elongated structure, the counterforce is a superimposition of the drag forces in the carrier fluid with gravity. From the drawing it can also be seen that in general the cutting volume comes to lie between the excitation coils. Assuming constant current density across the cross sections of the excitation coils, the desired constancy can be obtained with a coil pair with a non-rectangular cross-section or with several coil pairs with a rectangular cross-section reach the density of the cutting force via the cutting volume or the desired adaptation to the spatially variable counterforce. When using coil pairs with different current densities in the individual, arbitrarily shaped coil partial cross sections, the desired constancy of the cutting force density over the cutting volume or the desired adaptation to the spatially variable counterforce can be achieved. PATENT CLAIMS 1. Magnetic separator, whereby the magnetic field, which generates the force density in the separating volume, which is necessary for the separation with high selectivity and the counterforce, is largely induced by the shape and position of the excitation coils, according to patent no. 379 525, characterized in that in the parting volume (7) the magnetic induction is approximately perpendicular to the gradient of the magnetic field 2. Magnetic separator according to claim 1, characterized in that the magnetic field is induced by rotationally symmetrical coils (3), (4), (5), (6), which are arranged symmetrically to the cutting volume (7) and in relation to the plane of symmetry (2nd ) flow through in the same direction and encompass the cutting volume (7) and the radius of the center of the cutting volume (7) is smaller than the largest radius of the excitation coils (5), (6), but larger than the smallest radius of the excitation coils (3), ( 4). 3. Magnetic separator according to claim 1, characterized in that the magnetic field is induced by elongated coils (3), (4), (5), (6), the long sides of the coil being arranged symmetrically to a plane of symmetry (2) and symmetrically to Plane volume (7) arranged in the plane of symmetry (2). 4. Magnetic separator according to one of claims 1 to 3, characterized in that the excitation coil (3), (4), (5), (6) made of metallic material such as. B. copper, aluminum and. Like. Are manufactured. 5. Magnetic separator according to one of claims 1 to 3, characterized in that the excitation coils (3), (4), (5), (6) are made of superconductors. 6. Magnetic separator according to one of claims 1 to 5, characterized in that one or more iron cores or iron yokes are provided to increase the magnetic induction or to reduce the number of ampere turns. 7. Magnetic separator according to one of claims 1 to 5, characterized in that one or more iron yokes or a normally conductive or a superconducting surface are provided for shielding the magnetic field. Add 1 sheet of drawing -4-