FR2657544A1 - MAGNETIC PARTICLE SEPARATOR AND NON-FERROUS METAL PIECES. - Google Patents

Abstract

The invention relates to a magnetic separator for particles and pieces of non-ferrous metal comprising a conveyor belt on which said particles are poured, this conveyor belt partially wound around an active cylindrical envelope with a horizontal axis of rotation designed made of a non-conductive material and inside which is mounted, coaxially, a magnetic system subjected to a speed of rotation greater than that of said active cylindrical envelope. This magnetic separator is characterized in that it comprises means (17, 18) for varying, on the one hand, the length (19) of the partial winding of the conveyor belt (2) around the cylindrical casing. active active (5) and, on the other hand, the zone (20) on the latter where this partial winding takes place.

Description

The invention relates to a magnetic separator for particles and pieces

  non-ferrous metal comprising a conveyor belt on which said particles are poured, said conveyor belt partially wrapping around an active cylindrical envelope with horizontal axis of rotation made of a non-conductive material and inside which is mounted, coaxially, a magnetic system subjected to a speed of

  rotation greater than that of said active cylindrical envelope.

  The present invention will find its application in the field of industrial recycling of waste compounds, mainly products

non-ferrous metals.

  The current separation of FOUCAULT, based on the principle that conductive materials undergo, through an alternating magnetic field, a different influence according to their conductivity coefficient, is well known However, its application on the industrial level poses a problem. number of problems due, in particular, to low

separation it provides.

  Thus, more particularly, US-A-3,448,857 discloses an industrial magnetic separator operating according to the above principle. This magnetic separator consists of a strip fed with particles and non-ferrous pieces, this strip coming to be wrapped partially around an active cylindrical envelope and designed in a non-conductive material In fact, inside this envelope is

  arranged, coaxially, a magnetic system, also called, polar wheel.

  More specifically, this magnetic system consists of a succession of permanent magnets or electromagnets arranged radially relative to an axis of rotation corresponding to the axis of rotation of the cylindrical envelope In fact, the latter is animated by a rotation speed that is noticeably slower than that of the pole wheel so that particles and non-ferrous pieces are effectively subjected to a field

alternating magnetic.

  Ultimately, the combination of the speed of movement of the conveyor belt and the influence of the polar wheel has the consequence of subjecting these particles and non-ferrous pieces to a speed whose value of the horizontal component differs according to their conductivity, this resulting in a distinct fall trajectory and, ultimately, their

  reception in different containers.

  The disadvantage associated with such a magnetic separator is that the zone of influence of the particles and non-ferrous pieces is too great, the conveyor belt winding for half around the cylindrical envelope to the dimensions adjusted to the polar wheel In fact, this has the consequence of subjecting said particles and non-ferrous pieces not only to acceleration with horizontal components, but also to a vertical acceleration when leaving the conveyor belt. This obviously results in a restriction of the effects. first search for a slight distinction of the trajectories of particles and pieces,

  leading to a significant reduction in the efficiency of the separation.

  In order to overcome the aforementioned problem and to limit the influence of the polar wheel on the non-ferrous particles at the level of the upper zone of the cylindrical envelope, it has been conceived a magnetic separator which, the polar wheel is eccentric to the inside this cylindrical envelope, its diameter being reduced by half compared to the latter.

  magnetic separator is described in particular in EP-A-0 339 195.

  In this prior document, reference is also made to means making it possible to tilt the polar wheel with respect to the axis of rotation of the cylindrical envelope to adjust, at the level of the latter, the zone

  influence of the particles to be separated.

  Although such an arrangement makes it possible to render negligible the vertical accelerations undergone by the ferrous particles and pieces under the influence of the polar wheel, they are also accompanied by a

  reduction in general of this influence.

  Indeed, in this regard, it should be noted that the alternating magnetic field, produced by the rotating pole wheel, tends to decrease rapidly when one deviates from the latter Also, should be respected, between this polar wheel and the cylindrical envelope, an air gap that is reduced as much as possible Or, having to do with an eccentric polar wheel inside the cylindrical envelope, the minimum air gap is located along a generator of the latter, this gap increasing on either side of this generator leading to a lesser influence of the particles and non-ferrous pieces Again, the results obtained by means of such magnetic separators are unsatisfactory, the performance of the

separation being mediocre.

  The present invention aims to overcome all of the aforementioned disadvantages by providing a magnetic separator which is capable of subjecting the particles and non-ferrous pieces to a sufficient influence of an alternating magnetic field while avoiding conferring them, by through this influence, accelerations with vertical components so that the path taken is sufficiently distinctive as a function of their conductivity allowing, finally, a separation at

high efficiency.

  To this end, the invention relates to a magnetic separator of particles and pieces of non-ferrous metals, comprising a conveyor belt on which are poured said particles and pieces of non-ferrous metals, this conveyor belt partially wrapping around an envelope cylindrical active horizontal axis of rotation designed in a non-conductive material and inside which is mounted, coaxially, a magnetic system subjected to a speed of rotation greater than that of said active cylindrical envelope, magnetic separator characterized by the fact that it comprises means for varying, on the one hand, the length of the partial winding of the conveyor belt around the active cylindrical envelope and, on the other hand, the zone on the latter is effected

this partial winding.

  In fact, the object of the present invention is that the maximum zone of influence of the particles on the conveyor belt is not limited to the level of a generator of the latter, but that, for all that, it does not follow. not a vertical component acceleration of the

  particles and non-ferrous pieces to separate.

  The obvious advantage obtained through this invention is an amplification of the phenomenon of separation, resulting in a very clear distinction between the trajectories taken by the particles as a function of their conductivity, which ultimately makes it possible to obtain

  particularly high separation efficiencies.

  Other objects and advantages of the present invention will be apparent from

  course of the following description concerning only one mode of

  realization which is given only indicative and not limiting.

  The understanding of this description will be facilitated by referring to

  annexed drawing and in which: FIG. 1 is a diagrammatic representation of the separator

  magnetic object of the present invention.

  The invention relates to a magnetic separator 1 for the recovery of waste consisting mainly of particles and non-ferrous metal pieces and, thereby, sorting them according to their conductivity. More specifically, this magnetic separator 1, as shown in Figure 1 comprises a conveyor belt 2 on which are discharged particles and pieces 3 to sort This conveyor belt 2 is wound, partially and substantially at its end downstream 4, around a cylindrical envelope 5, with a horizontal axis of rotation 8, incorporating a magnetic system 6 capable of subjecting said

  particles and pieces 3 to an alternating magnetic field.

  In fact, the interaction of this alternating magnetic field and FOUCAULT currents thus induced results in the creation of forces acting differently on the particles and pieces as a function of their conductivity, a force influencing the drop trajectory of these particles and

  pieces when they come to leave the conveyor belt 2.

  More precisely, this magnetic system 6 is similar to a pole wheel arranged coaxially inside said cylindrical envelope 5 and consists of a plurality of permanent magnets or electromagnets 7 arranged

  radially with respect to the axis of rotation 8.

  In order to subject the particles and pieces 3 to an alternating magnetic field, this magnetic system 6 is subjected to a rotation whose speed is substantially greater than that of the cylindrical envelope 5 which

  is dependent on the speed of travel of the conveyor belt 2.

  It should be noted, moreover, that the latter evolves in a closed circuit and, as a result, comes to wind, partially, around a return roller 9 disposed in the upstream part 10, this conveyor belt 2 defining, thus , an upper strand 11 on which the particles 3 and a

  lower strand 12 ensuring looping of the circuit.

  In view of the foregoing description, it is understood that in the course of

  operation of the magnetic separator 1, the particles and pieces, initially deposited on the upper strand 11 of the conveyor belt 2, evolve towards the cylindrical envelope 5 containing the magnetic system 6 Then, under the effect of the speed in advance of the conveyor belt 2 and the influence produced by this magnetic system 6, these particles and pieces 3 follow a drop trajectory 13, 14 which differs according to their conductivity coefficient. These particles 3 are thus

  sorted and recovered in separate containers 15, 16.

  In fact and according to one characteristic of the present invention, this magnetic separator 1 comprises means 17, 18 making it possible, on the one hand, to vary the partial winding length 19 of the conveyor belt 2 around the cylindrical envelope 5 and, on the other hand, to modulate the location on the latter of the zone 20 o is carried out this partial winding. In fact, the objective of such means 17, 18 is that it is possible to subject the particles and pieces 3 to an alternating magnetic field of maximum intensity so as to obtain a maximum yield of the effect produced. resulting in distinct trajectories of fall according to their conductivity Also, it will be necessary to avoid, through these means 17, 18 that this prolonged influence suffered by the particles 3 via the magnetic system 6 lead to accelerations with vertical components of said particles and pieces 3 which would have for

  consequence of lessening the desired effects.

  According to a preferred embodiment of the present invention, these means 17, 18, making it possible to vary the partial winding length 19 of the conveyor belt 2 around the cylindrical envelope 5 while allowing the displacement of this zone of 20 around the latter, consist on the one hand, by means of height adjustment of the deflection roller 9 disposed in the upstream portion 10 of the circuit of the strip

conveyor 2.

  On the other hand, these means are completed by a second roller 21 disposed below the cylindrical envelope 5 and around which comes

  partially wind the conveyor belt 2.

  This roller 21 is, moreover, associated with adjustment means in

  height and in a horizontal direction.

  According to a first embodiment, the roller 21 is only a

non-magnetic return roller.

  According to a second embodiment, the roller 21 comprises a magnetic system 6 with a permanent or electromagnetic magnet making it possible to treat the more or less ferromagnetic residual particles and pieces.

  case, these are recovered in an additional container 50.

  In sum, by means of the height adjustment means 17 of the deflection roller 9, it is possible to modify the coordinates, according to a fixed reference (X, Y) 23, of the location 22 o the conveyor belt 2 between in contact with the cylindrical casing 5 While the second deflection roller 21 is capable of acting on the coordinates, relative to this fixed reference 23, of the point 24 o this conveyor belt 2 comes again to

leave the cylindrical envelope 5.

  Thus, the lowering of the deflection roller 9 is achieved by means of the height adjustment means 17 so as to give the upper strand 11 of the conveyor belt 2 an inclination 25 with respect to the horizontal tending to impart to the particles and pieces 3 upward movement towards the cylindrical envelope 5, the earlier makes contact between the latter and said conveyor belt 2, contributing to a

increase of zone 20.

  It should be noted, moreover, that such an inclination 25 of the conveyor belt 2 makes it possible to increase the distance 26 traveled by the particles and pieces 3 during their fall, which makes it possible to increase the differences observed between two particles and pieces of different conductivity, precisely at the point of their fall. This facilitates, of course, their

  recovery in separate containers.

  This zone 20 of influence of the magnetic system 6 on the particles and pieces 3 can be further increased or, on the other hand, decreased when the deflection roller 21 is pivoted counterclockwise, respectively, in the direction of the needles. A watch around the cylindrical casing 5 More precisely, it suffices to modify the angle 21a formed by the strand 21b described by the conveyor belt 2 between this return roller 21 and

  the cylindrical envelope 5 and, in relation to the vertical.

  It is thus possible to limit this zone of influence 20 substantially in the upper part of the cylindrical envelope 5 and thereby avoid subjecting the particles and pieces 3 to a vertical acceleration under

  the pulse of the rotating magnetic field.

  According to a preferred embodiment, the return roller 9, disposed in the upstream portion 10, is mounted on an axis 27 whose ends are slidable in oblong shaped slots 28 arranged at vertical supports 29 made integral with the chassis of the

machine (not shown).

  Furthermore, with regard to the return roller 21, it can be mounted on an axis 30 whose ends can also slide in oblong slots 31 arranged vertically and made in supports 32 movable in the horizontal direction on the frame to which they are attached Note, however, that an opposite arrangement can be adopted of making the supports 32 movable in the vertical direction while allowing a certain mobility of the axis 30 of the return roller 21 in oblong slots 33 machined in the horizontal direction at the level of said

  supports 32 Figure 1 shows the two possible embodiments.

  This same FIG. 1 also illustrates, in broken lines, a third embodiment of the means allowing the return roller 21 to pivot around the cylindrical envelope 5. , on which is mounted the return roller 21, is able to move, at its ends, in oblong slots 34, this time, in the end 35 of the support arms 36 mounted pivoting around the l rotation axis 8

  corresponding to the axis of rotation of the cylindrical envelope 5.

  In all cases, it is understood that in the various embodiments described above, it is possible to modify the arrangement of the

  16 return roller 21 in both a horizontal and vertical direction.

  This characteristic allows, moreover, this return roller 21 to ensure

  the tensioning of the conveyor belt 2.

  It is probable that having determined the length 19 of the zone of influence for maximum efficiency, this length 19 is to be retained for sorting a whole range of nonferrous metal particles and pieces with different conductivity coefficients and that only the tilt angle 25

  upper strand Il corresponding to the conveyor belt 2 is to be modified.

  In this case, it is recommended to make integral the axes 27 and 30, corresponding, respectively, to the return roller 9 and the return roller 21, by means of connecting arms 37 (illustrated in broken lines in the drawing) thus a given displacement of said return roller 9 corresponds to a displacement of identical amplitude of the return roller 21. The length 19 of the zone of influence 20 is thus maintained. In addition, this arrangement avoids taking up the tension of the conveyor belt 2 to

different settings.

  The present invention also proposes to avoid any deterioration of the cylindrical envelope 5 in the event of insertion of a ferromagnetic particle or piece found by chance in the particles and non-ferrous pieces between the latter and the strip. In particular, in case of occasional wear of the latter, not justifying, however, its replacement, it is likely that some ferromagnetic particles or pieces found by chance in the particles and non-ferrous pieces are becoming embedded in the conveyor belt 2 at the level of this wear and finally fit between the conveyor belt 2 and the cylindrical envelope 5 Gold, if this particle or piece

  ferromagnet found by chance in particles and non-ferrous particles

  ferrous is maintained for a prolonged period under the influence of the alternating magnetic field, it is brought to heat up strongly tending to

  destroying the cylindrical shell 5 made of a non-conductive material.

  Also, it is strongly advised to collect, as quickly as possible, this particle or ferromagnetic piece found by chance in the particles and non-ferrous pieces of the outer surface of this envelope.

cylindrical 5.

  For this purpose, use is made of a wiper 38 of hemi-cylindrical shape with a radius greater than the radius of the cylindrical casing 5 and disposed between the upper strand 11 and the lower strand 12 of the conveyor belt 2 This wiper 38 is mounted pivoting about a horizontal axis 39 situated substantially downstream from its vertical median plane so as to create an imbalance tending to maintain one of the ends 41 of this wiper 38 applied against the cylindrical envelope 5 end 41 of the wiper 38 acting tangentially is preferably of tapered shape this

which contributes to its effectiveness.

  In the case of using a roller 21 provided with a magnet system with a permanent or electromagnetic magnet, this roller 21 is

also provided with a scraper 38.

  Thus, in case of introduction between the cylindrical casing 5 and the conveyor belt 2 of a ferromagnetic particle found by chance in the non-ferrous particles or pieces, it is immediately removed from the periphery of this cylindrical envelope 5 under the action of the scraper 38 It is then removed from the magnetic system 6 by progressing along the lower surface 42 of said scraper 38 This ferromagnetic particle found by chance in the non-ferrous particles or pieces then comes to fall on the lower strand 12 of the conveyor belt 2 A second

  Finally, the scraper 43 ensures the ejection at the side portions.

  In view of the foregoing, it is understood that the magnetic separator object of the present invention has the advantage of optimized operation leading to high separation rates. Also, such magnetic separators, according to the invention, provide , a solution to the problem posed so far by the industrial application of separators

by current of FOUCAULT.

  Although the invention has been described with respect to a particular embodiment, it is understood that it is in no way limited and that various modifications of shapes, materials and combinations thereof can be made. various elements, without departing from the framework and

the spirit of the invention.

Claims (11)

claims   1 magnetic separator (1) of particles and pieces of metal (3) of non-ferrous metal comprising a conveyor belt (2) on which said particles (3) are poured, this conveyor belt (2) winding, partially, around an active cylindrical envelope (5) with a horizontal axis of rotation (8) made of a non-conductive material and inside which is mounted, coaxially, a magnetic system (6) subjected to a speed of rotation greater than that of the active cylindrical envelope (5), magnetic separator (1), characterized in that it comprises means (17, 18) for varying, on the one hand, the length (19) of the partial winding of the conveyor belt (2) around the active cylindrical envelope (5) and, on the other hand, the zone (20) on this   last o is carried out this partial winding.   Magnetic separator according to Claim 1, characterized in that the means (17) consist of a deflection roller (9) arranged in the upstream part of the conveyor belt circuit (2) and around which it coils. partially, the latter, this return roller (9) being associated with height adjustment means for modifying the inclination (25), relative to the horizontal, formed by the upper strand (11) of the conveyor belt ( 2) extending between this return roller   (9) and said cylindrical shell (5).   Magnetic separator according to claims 1 and 2, characterized   in that the means (17, 18) are completed by a second roller (21) arranged below the cylindrical envelope (5) and around which the conveyor belt (2) is partially wound, this second roller (21) being associated with means of adjustment in height and in a horizontal direction for changing the angle (21a) described by the strand (22b) formed by the conveyor belt (2) between the second roller   (21) and the cylindrical envelope (5) and that, relative to the vertical.   Magnetic separator according to claim 3, characterized in that   that the roller 21 is a non-magnetic return roller.   Magnetic separator according to claim 3, characterized in that the roller 21 comprises a magnetic system 6 with permanent or electromagnetic magnet for treating the particles and the pieces more or less residual ferromagnetic.   6 Magnetic separator according to claim 2, characterized in that the return roller (9) is mounted on an axis (27) whose ends are likely to move in oblong slots   (28) formed in vertical supports (29).   Magnetic separator according to claim 3, characterized in that the deflection roller (21) is mounted on an axis (30) whose ends are capable of moving in vertical oblong slots (31) machined in supports (32). ) able to move next a horizontal direction.   8 magnetic separator according to claim 3, characterized in that the return roller (21) is mounted on an axis (30) whose ends are capable of moving in horizontal oblong slots (33) formed in supports (32). ) movable in the vertical direction.   9 magnetic separator according to claim 3, characterized in that the return roller (21) is mounted on an axis (30) whose ends are able to move in oblong slots (34) formed in the end (35). ) support arms (36) pivotally mounted about an axis of rotation (8) corresponding to the axis of rotation of the cylindrical envelope (5).   Magnetic separator according to Claims 6 to 9, characterized   in that the return roller (9) is associated with the deflection roller (21) via connecting arms (37) cooperating with their axis (27, ).   11 Magnetic separator according to claim 1, characterized in that it comprises a wiper (38) of hemi-cylindrical shape pivotally mounted about a horizontal axis (39) and situated between the upper strand (11) and the lower strand ( 12) described by the conveyor belt (2), one of the ends (41) of this scraper (38) cooperating tangentially with the cylindrical envelope (5).   Magnetic separator according to claims 1 and 11, characterized   in that it comprises a second scraper (43) cooperating with the lower strand (12) of the conveyor belt (2) to take out the particles   (3) and ensure the ejection at the side parts.   Magnetic separator according to Claims 1 and 5, characterized   in that the roller (21) provided with the magnetic magnet system (6)   permanent or electromagnetic comprises a scraper (38).