Magnetic separator

Abstract

A weak magnetic force magnetic separator, including: a belt conveyor conveying separation target particles; and a suspended magnet unit provided at a distance above the belt conveyor and configured to magnetically attract, with a uniform, weak magnetic force, the separation target particles conveyed over a belt. With a length of the magnet unit in its longer direction being greater than a belt width of the belt, and with the magnet unit placed such that its longer direction is aligned with the belt width direction and its both ends overhang the belt width, and such that a distance from the surface of the belt is constant across its longer direction, magnetic flux density variations in the belt width direction over the belt surface facing the magnet unit are 10% or less within a weak magnetic force range of from over 0 to 700 gauss.

Claims

1. A weak magnetic force magnetic separator, comprising: a belt conveyor configured to convey separation target particles; and a suspended magnet unit provided above the belt conveyor at a distance from the belt conveyor, wherein said weak magnetic force magnetic separator, further comprises at least one swing pin-gate above the belt of the belt conveyor, wherein the separation target particles conveyed over the belt are prompted to change postures over the belt upon contacting a pin of the pin-gate, wherein the magnet unit magnetically recovers ferromagnetic bodies and refuses to magnetically recover weakly magnetic bodies by magnetically attracting, with a uniform, weak magnetic force, the separation target particles conveyed over a belt of the belt conveyor, wherein with a length of the magnet unit in its longer direction being greater than a belt width of the belt, and with the magnet unit placed such that its longer direction is aligned with a direction of the belt width and its both ends overhang the belt width, and such that a distance from a surface of the belt is constant across its longer direction, variations in magnetic flux density in the direction of the belt width over the surface of the belt facing the magnet unit are 10% or less within a weak magnetic force range of from over 0 gauss to 700 gauss and wherein the weak magnetic force magnet separator separates the separation target particles based on shapes thereof into those having a shape that rolls down an inclined surface by gravity and those having a shape that does not roll down the inclined surface by gravity, by inclining the belt of the belt conveyor toward a direction that is at a right angle from a moving direction of the belt.

2. A method of separating highly concentrated tantalum capacitor products from separation target particles wherein the separation target particles are obtained from elements stripped and recovered from used printed circuit boards after a step of primary concentration followed by a step of secondary concentration, wherein the step of primary concentration comprises of recovering particles that are in a same dimension range as that of tantalum capacitors from elements stripped and recovered from used printed circuit boards, and wherein the step of secondary concentration comprises recovering separation target particles that are in a same specific gravity range as that of the tantalum capacitors from the particles recovered by the step of primary concentration, said method comprising providing the weak magnetic force magnetic separator according to claim to 1 and obtaining from the separation target particles, particles that are discharged from the belt conveyor without being magnetically recovered, as highly concentrated tantalum capacitor products.

Description

BRIEF DESCRIPTION OF DRAWINGS

(1) FIG. 1 is a diagram showing a magnetic flux density distribution in the direction of a belt width, corresponding to the distance between a suspended magnet unit and a belt.

(2) FIG. 2 is a diagram explaining behaviors of particles over an inclined belt when an inclined belt is used.

(3) FIG. 3 is a diagram showing an example of a swing pin-gate placed above a belt.

DESCRIPTION OF EMBODIMENTS

Examples

(4) The present invention is a weak magnetic force magnetic separator, including: a belt conveyor configured to convey separation target particles; and a suspended magnet unit provided above the belt conveyor at a distance from the belt conveyor, wherein the magnet unit magnetically recovers all ferromagnetic bodies and magnetically recovers none of weakly magnetic bodies by magnetically attracting, with a uniform, weak magnetic force, the separation target particles conveyed over a belt, and wherein with a length of the suspended magnet unit in its longer direction being greater than a belt width, and with the magnet unit placed such that its longer direction is aligned with a direction of the belt width and its both ends overhang the belt width, and such that the distance from a surface of the belt is constant across its longer direction, variations in magnetic flux density in the direction of the belt width in a surface region of the belt facing the magnet unit are 10% or less within a weak magnetic force range of from over 0 gauss to 700 gauss. The present invention employs a suspended magnet unit instead of a roll type such as a magnet pulley that tends to produce magnetic force variations over the belt, and does not use both ends of the magnet unit that tend to produce magnetic force variations. Therefore, the present invention can realize a magnetic separator that magnetically recovers all ferromagnetic bodies and magnetically recovers none of weakly magnetic bodies by magnetically attracting, with a uniform, weak magnetic force, separation target particles conveyed over a belt.

(5) For example, in a prototype model, a plate magnet having a length of 45 cm in its longer direction is used as a suspended magnetic separator, with respect to a belt width of 30 cm. If necessary, the suspended magnet may be provided with a vertical micro-motion device, to have a function of moving upward and downward within a range of from 2 cm to 50 cm from the surface of a belt by a millimeter unit. With this configuration, the magnetic separator covers a very low magnetic flux density range of roughly from over 0 gauss to 700 gauss (from over 0 tesla [T] to 0.07 tesla [T]), and can suppress variations in magnetic flux density over a surface of the belt to roughly 10% or less as shown in FIG. 1. In FIG. 1, the vertical axis represents magnetic flux density [tesla] ([T]), and the horizontal axis represents a belt width (a distance from the center) [mm]. FIG. 1 plots magnetic flux density distributions in the direction of the belt width when the distance between the suspended magnet unit and the belt is 0 mm (i.e., the suspended magnet unit is on the belt surface), 25 mm, 50 mm, 75 mm, and 100 mm, respectively. It can be seen that there are almost no variations in the magnetic flux density distributions.

(6) Furthermore, the present invention incorporates into the weak magnetic force magnetic separator described above, a new feature for promoting shape separation by inclining the belt of the belt conveyor toward a direction that is at a right angle from the moving direction of the belt as shown in FIG. 2, to thereby make the magnetic separator serve also as a shape separator, and enable this apparatus, although being compact, to perform highly precise separation into three components, namely spherical/cylindrical particles, ferromagnetic particles, and remaining particles.

(7) For example, a case of separating electronic elements stripped from waste printed circuit boards into respective kinds will be considered. Electronic elements include flat elements such as ICs and memories, rectangular-parallelepiped elements such as tantalum capacitors, and cylindrical elements such as aluminum electrolytic capacitors. Because there exist almost no spherical particles, elements that are expected to roll down an inclined belt are aluminum electrolytic capacitors.

(8) In FIG. 2, a reference sign 1 denotes a suspended magnet unit, a reference sign 2 denotes a belt, a reference sign 3 denotes a sample supply position, a reference sign 4 denotes cylindrical particles, a reference sign 5 denotes nonmagnetic and weakly magnetic block-rectangular particles, a reference sign 6 denotes ferromagnetic block-rectangular particles, a reference sign X denotes a belt conveying direction, and a reference sign denotes incline of a belt surface of the belt 2. As shown in FIG. 2, the inclination is expressed as leftward dangling (or rightward dangling) of the belt surface of the belt 2 from a horizontal surface when seen in the belt conveying direction.

(9) When a cylindrical aluminum electrolytic capacitor is supplied onto a mere inclined belt 2, there are a case when it immediately roll downward, and a case when it does not roll but is conveyed by the conveyor. The former is a case when the cylindrical shape is supplied with its side surface turning to the inclination direction (the cylindrical particle 4 represented by A in FIG. 2). The latter is a case when an end surface of the cylindrical shape turns to the inclination direction (the cylindrical particle 4 represented by B in FIG. 2). In the latter case, unless the cylindrical particle is rolled down the inclined surface before the conveyor arrives at the terminal point, the precision of shape separation becomes poor.

(10) Hence, the present invention sees to it that the particle B of which end surface turns to the inclination direction (i.e., of which side surface turns to the conveying direction) immediately rolls down the inclined surface, by providing the weak magnetic force magnetic separator with a thin pin obstacle above the belt halfway of conveyance by the conveyor, to let the cylindrical particle change postures upon contacting the obstacle and its side surface turn to the inclination direction during the process of changing postures. Here, the pin must be fixed in the apparatus in the form of being suspended from above the belt. Further, in order to ensure a contact with the particle, it is preferable to provide not one pin, but many in the inclination direction. However, if there are too many pins to make the interval between the pins narrow, particles cannot pass through the pins, but accumulate and cause blocking. If the interval between the pins is broad, there will be many particles that go without contacting the pins. Hence, swing pin-gates are employed in order to prevent blocking by accumulation of particles and keep secure contacts of the pins with particles. As shown in FIG. 3, a swing pin-gate is a plate (pin gate 10) that includes multiple pins 11 attached to a rotation shaft 12 rotatable in the forward direction of the belt conveying direction X, and is hung from above the belt 2 like a curtain. When having no contact with a particle, the pin-gate 10 is hung perpendicularly to the belt 2 by gravity. Upon contacting a particle, the pin-gate 10 prompts the particle to change postures, while also swinging about the rotation shaft 12 to the moving direction of the belt 2 due to the move of the particle accompanying the move of the belt 2 to thereby prevent blocking by the particle. The side surface of a particle may not turn to the inclination direction only by making contact once. Therefore, in order to make this sure, it is preferable to provide the pin gates 10 at three or more locations.

(11) The weak magnetic force magnetic separator of the present invention is applicable to a plurality of variously mixed kinds of particles of from 0.1 mm or mainly 1 mm to 80 mm (or preferably 30 mm). One typical application target is electronic elements stripped from waste printed circuit boards. The present inventors have already filed a patent application for a tantalum capacitor recycling method of PTL 7, which is a method for extracting only tantalum capacitors at a high concentration from mixed electronic elements through three steps of screening (sieve separation), gas stream separation, and magnetic separation. As a method for removing crystal oscillators that are co-present with tantalum capacitors after gas stream separation, PTL 7 expressly describes magnetic separation with a usually rarely employed weak magnetic force of 240 gauss (0.024 tesla), as a condition for magnetically attracting only crystal oscillators and not magnetically attracting tantalum capacitors irrespective of whether tantalum capacitors have a lead wire or not. The weak magnetic force magnetic separator of the present invention is an apparatus that can not only satisfy this condition, but also recover cylindrical aluminum electrolytic capacitors individually with an inclined belt.

(12) The weak magnetic force magnetic separator of the present invention that realized a uniform, weak magnetic force, and its conveyor were able to realize more highly precise element separation in a tantalum capacitor recovery test, when they were provided with a function as an inclined belt shape separator with swing pin-gates, based on the tantalum capacitor recycling method of PTL 7. Specifically, when a mixed element mock sample having a similar particle diameter and specific gravity to those of tantalum capacitors (i.e., extremely difficult to separate) was subjected to a test for removing crystal oscillators and aluminum electrolytic capacitors (which were impurities) co-present with tantalum capacitors, crystal oscillators could be removed with the weak magnetic force magnetic separation function, and aluminum electrolytic capacitors could be removed with the inclined belt separation function. Further, the apparatus of the present invention, although compact, is capable of continuous supply and discharge, can process about 20 kg/h of elements with a conveyor having a length of 1 m, and about 40 kg/h of elements with a conveyor having a length of 2 m, and is very practical.

INDUSTRIAL APPLICABILITY

(13) The present invention has been developed mainly as a weak magnetic force magnetic separator in a recycling industry, but is applicable not only to a recycling industry but also as a weak magnetic force magnetic separator in all technical fields in which separation is performed with a weak magnetic force, such as material control in a manufacturing industry.

REFERENCE SIGNS LIST

(14) 1 suspended magnet unit 2 belt 3 sample supply position 4, A, B cylindrical particles 5 nonmagnetic and weakly magnetic block-rectangular particles 6 ferromagnetic block-rectangular particles 10 pin-gate 11 pin 12 rotation shaft X belt conveying direction incline