JPH0677834U - Non-magnetic metal sorter - Google Patents

Abstract

(57) [Abstract] [Purpose] To provide a device for separating non-magnetic metal from other materials by utilizing eddy current caused by a rotating magnetic field, which can fly the non-magnetic metal far and improve the selection efficiency. To do. [Structure] In a belt conveyor 10, a non-metal top pulley 11 and a belt 13 form a conveying path structure 10x. Inside the top pulley 11, that is, below the end of the transport path forming body 10x, a first rotating body 20 having different magnetic poles alternately arranged on the outer periphery is arranged. The second rotating body 30 is arranged above the end portion of the transport path constructing body 10x apart from the upper surface of the transport path constructing body. The second rotating body also has different magnetic poles alternately arranged on the outer circumference. When the first rotating body 20 is rotated by the motor 22, the second rotating body 30 is rotated by the magnetic attraction so that the magnetic poles different from the magnetic poles of the first rotating body 10 face each other with the transport path forming body 10x interposed therebetween. .

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to an apparatus for selecting and recovering valuable non-magnetic metal from oversized waste generated in cities, crushed materials of scrapped vehicles, and the like.

[0002]

[Prior art]

 As disclosed in JP-A-3-68463, a device for selecting a nonmagnetic metal from among a magnetic metal, a nonmagnetic metal and a nonmetal is known. The sorting device of this publication includes a belt conveyor and a rotating body having different magnetic poles alternately arranged on the outer circumference. The belt conveyor has a top pulley, an end pulley, and an endless belt stretched between them. The top pulley is made of non-metallic material and is hollow. The rotating body is housed inside the top pulley. This rotating body rotates faster than the pulley. Among the crushed materials such as junk cars carried on the belt, non-metallic materials fall horizontally from one end of the belt conveyor (the end on the top pulley side) at the belt transportation speed. Further, since the magnetic metal is attracted to the magnetic poles of the rotating body, it reaches the lower part of the belt conveyor, and the attracting force of the magnetic poles weakens before dropping. An eddy current is generated in the non-magnetic metal due to the magnetic induction effect caused by the high speed rotation of the rotating body, and the non-magnetic metal is generated by the interaction between the magnetic field caused by this eddy current and the magnetic field caused by the magnetic pole of the rotating body. Repulsive force in the direction of centrifugal force and thrust (acceleration force) in the tangential direction act on metal. Therefore, the non-magnetic metal flies obliquely upward from the belt conveyor and falls in a parabola different from that of the non-metal. Specifically, non-magnetic metals fly farther than non-metals. In this way, the nonmagnetic metal is separated and recovered from the magnetic metal and the nonmetal.

[0003]

[Problems to be solved by the device]

 In the above-mentioned sorting apparatus, if the acceleration force to the non-magnetic metal generated by the eddy current is weak, there will be no significant difference between the parabola drawn by the non-magnetic metal and the parabola drawn by the non-metal, and the above-mentioned sorting accuracy will deteriorate. Therefore, attempts were made to increase the acceleration force acting on the non-magnetic metal by increasing the magnetic field strength of each magnetic pole of the rotating body or increasing the rotating speed of the rotating body, but the sorting accuracy was not as high as expected. The reason is as follows. (I) As described above, the magnetic induction stress acting on the non-magnetic metal includes an upward vertical component, and when the non-magnetic metal enters the magnetic field of the magnetic pole of the rotating body, the non-magnetic metal induces the magnetic induction. Flying above the conveyor due to the vertical component of stress. On the other hand, as is well known, since the strength of the magnetic field is inversely proportional to the square of the distance, the accelerating force acting on the nonmagnetic metal is rapidly weakened during the upward flight. Therefore, the accelerating force of the belt conveyor in the conveying direction does not act continuously, and sufficient forward kinetic energy cannot be obtained. (Ii) Further, since the strength of the magnetic field is inversely proportional to the square of the distance, the forward acceleration acting on the nonmagnetic metal is large at the lower part of the nonmagnetic metal (the part close to the magnetic pole of the rotating body) and at the upper part ( It is small in the part far from the magnetic pole of the rotating body. Therefore, a part of the kinetic energy of the non-magnetic metal due to the magnetic induction stress is consumed as the rotation energy of the non-magnetic metal.

[0004]

[Means for Solving the Problems]

 The present invention has been made to solve the above-mentioned problems, and its gist is (a) a non-metallic carrier path structure, and (b) an end part of the carrier path structure, which is disposed below the end of the carrier path structure. In a non-magnetic metal sorting apparatus provided with a first rotating body having different magnetic poles alternately arranged on the circumference, (c) further away from the upper surface of the transport path constituting body above the end of the transport path constructing body. Characterized in that different magnetic poles are alternately arranged on the outer periphery, and the second rotary body is provided so as to rotate so that the magnetic pole different from the magnetic pole of the first rotary body faces the transport path forming body. It is in a non-magnetic metal sorting device.

[0005]

[Action]

 With the rotation of the first and second rotating bodies, the different magnetic poles of both rotating bodies pass in the vicinity of the ends of the transport path constituting body while facing each other. At this time, an eddy current due to the magnetic induction action is generated in the non-magnetic metal that has moved along the transport path structure, and is formed by the magnetic field of this eddy current and the magnetic poles of the first and second rotating bodies. Acceleration acts on non-magnetic metal due to interaction with the magnetic field. In the magnetic field formed by the facing magnetic poles of the first and second rotating bodies, magnetic field lines connecting these magnetic poles are generated, so that the magnetic flux density is rapidly attenuated upward from the upper surface of the end portion of the transport path constituting body. It is almost constant without. For this reason, the non-magnetic metal on the transport path structure does not fly upward when entering the magnetic fields of the first and second rotating bodies, and it is possible to continuously receive a stable accelerating force and maintain a sufficient horizontal direction. Kinetic energy is applied and the particles are jetted away from the end of the transport path structure. As described above, since the change of the magnetic flux density is substantially constant from the upper surface of the end portion of the transport path structure upward, the acceleration forces acting on the lower part and the upper part of the non-magnetic metal are also substantially equal. Therefore, the rotation of the non-magnetic metal is prevented or suppressed, and the kinetic energy of the non-magnetic metal can be prevented from being consumed by the rotation energy. As a result, the non-magnetic metal can be more efficiently extracted from the end of the transport path structure. Can fly far.

[0006]

【Example】

 An embodiment of the present invention will be described below with reference to the drawings. The sorting apparatus shown in FIG. 1 includes a belt conveyor 10. The belt conveyor 10 has a top pulley 11, an end pulley 12, and an endless belt 13 stretched between them. The top pulley 11 is made of a non-metallic material such as FRP (fiber reinforced plastic) and has a tubular portion. The belt 13 is also made of non-metal. A motor 15 is connected to the end pulley 12 via a belt 14. The motor 15 drives the belt conveyor 10 so that crushed materials such as scrapped vehicles placed on the upper side of the belt 13 can be transferred to the top pulley 11 Is conveyed in the direction of arrow A. The crushed material contains a non-metal 1 such as rubber, glass, plastic, and wood chips, a magnetic metal 2, and a non-magnetic metal 3 such as aluminum. The upper part of the belt 14 and the top of the top pulley 11 are provided as a transport path structure 10x.

The sorting device further includes a first rotating body 20 and a second rotating body 30. These rotating bodies 20 and 30 have the same diameter. Different magnetic poles are alternately arranged at equal intervals on the outer circumference of each of the rotating bodies 20 and 30. The rotating bodies 20 and 30 have the same number of magnetic poles, and therefore the distances between the magnetic poles are also equal to each other.

The first rotating body 20 is housed inside the top pulley 11. The first rotating body 20 is connected to a motor 22 (driving source) via a belt 21, and is rotated by this motor 22 at a speed much higher than the rotation of the top pulley 11. The rotating shaft 21 of the first rotating body 20 is displaced above the rotating shaft of the top pulley 11.

The second rotating body 30 is arranged above the first rotating body 20 and the top pulley 11, and is separated from the upper surface of the belt 13. The rotation shaft 31 of the second rotating body 30 is rotatably supported by the frame, and has no connection relationship with the motor. The rotating shaft 31 of the second rotating body 30 is deviated from the rotating shaft 21 of the first rotating body 20 toward the end pulley 12 side, and the straight line connecting the rotating shafts 21 and 31 of the rotating bodies 20 and 30 is a vertical line. Leaning against. This tilt angle is represented by Θ in FIG.

A partition plate 40 extends from the lower end of the second rotating body 30 toward the end pulley 12 in parallel with the belt 13. The partition plate 40 is made of a non-metallic material, for example, FRP, and prevents the magnetic metal 2 from being magnetically attached to the second rotating body 30. A collision plate 50 is arranged in front of the top pulley 20. Further, a storage box 61 is arranged below the top pulley 20, and further two storage boxes 62 and 63 are sequentially arranged in front of the storage arrangement 61.

In the sorting apparatus having the above-mentioned configuration, the crushed material such as the scrapped vehicle is carried toward the top pulley 11 by the belt conveyor 10. On the other hand, the motor 22 rotates the first rotating body 20 at a high speed. The second rotating body 30 rotates together with the first rotating body 20 due to the magnetic attraction between the magnetic poles of the rotating bodies 20 and 30. Therefore, the second rotating body 30 rotates synchronously with the first rotating body 10, and the magnetic poles of the first rotating body 20 and the second rotating body 30 that pass through the top of the top pulley 11 at the same time have different polarities. There is.

Among the crushed materials, the non-metal 1 is not affected by the magnetic fields of the first and second rotating bodies 20 and 30, so that the non-metal 1 is horizontally moved at the conveying speed of the belt conveyor 10 (top pulley). 11) and falls in a parabola and is accommodated in the accommodation box 62.

Since the magnetic metal 2 is attracted to the magnetic poles of the first rotating body 20, the magnetic metal 2 does not stick out from the end portion of the belt conveyor 10 and goes around the top pulley 11. Since the rotary shaft 21 of the first rotary body 20 is deviated upward with respect to the rotary shaft of the top pulley 11, the magnetic force of the magnetic pole of the first rotary body 20 acting on the magnetic metal 2 gradually weakens. Therefore, the magnetic metal 2 falls from the belt 13 below the top pulley 11 and is housed in the housing box 61.

When the non-magnetic metal 3 enters the magnetic fields of the first and second rotating bodies 20 and 30, an eddy current is generated in the non-magnetic metal 3 due to the magnetic induction effect accompanying the high-speed rotation of the rotating bodies 20 and 30. Due to the interaction between the magnetic field generated by the eddy current and the rotating magnetic field generated by the magnetic poles of the rotors 20 and 30, an acceleration force acts on the non-magnetic metal 3, and the non-magnetic metal 3 is indicated by an arrow H in FIG. Pop out in the direction indicated by. That is, the non-magnetic metal 3 jumps forward from the end of the belt conveyor 10 above the deviation elevation angle θ of the rotating bodies 20 and 30. Therefore, the non-magnetic metal 3 draws a parabola different from that of the non-metal 1, is blown farther than the non-metal 1, hits the collision wall 50, and is housed in the housing box 63.

Next, the magnetic induction stress acting on the non-magnetic metal 3 will be described in detail. Since the magnetic poles facing each other of the first and second rotating bodies 20 and 30 have different polarities, a magnetic force line connecting these magnetic poles is generated. Therefore, the magnetic flux density is almost constant from the top of the top pulley 11 upward without being rapidly attenuated. Therefore, the non-magnetic metal 3 can continuously receive a stable accelerating force without being jumped upward when entering the magnetic field of the first and second rotating bodies 20, and has a sufficient horizontal motion. It is given energy and can fly far ahead. Further, as shown in FIG. 2, since the acceleration forces acting on the lower part and the upper part of the non-magnetic metal 3 (indicated by arrows X ₁ and X ₂ respectively) are almost equal, rotation of the non-magnetic metal 3 is prevented. , It is possible to prevent kinetic energy from being consumed by rotation energy. From this point as well, the non-magnetic metal 3 can be blown far ahead. Therefore, it is possible to prevent the non-magnetic metal 3 from falling into the storage box 62 for the non-metal 1 due to a short flight distance, and it is possible to improve the selection efficiency.

Since the straight line connecting the rotary shafts 21 and 31 of the rotary bodies 20 and 30 is inclined by the angle Θ with respect to the vertical line, the protrusion angle of the non-magnetic metal 3 can be set upward. Can also increase the flight distance.

The present invention is not limited to the above embodiment, and various modes are possible. The transport path structure may be a chute that is inclined. In this case, the object to be sorted reaches the end of the chute by its own weight along the chute. The second rotating body may be rotated by a motor, and the first rotating body may be rotated by magnetic attraction. When one of the first and second rotating bodies is driven by a motor and the other is rotated together by magnetic attraction, only one motor is required, so the equipment cost is reduced, and control of synchronous rotation or the like is also unnecessary. . Both the first and second rotating bodies may be rotationally driven by a motor. In this case, it is necessary to match the rotation so that the magnetic pole different from the magnetic pole of the first rotating body always faces each other. The first and second rotating bodies may have different diameters. In this case, it is necessary to equalize the distance between the magnetic poles in the two rotating bodies and equalize the peripheral speeds.

[0018]

[Effect of device]

 As described above, according to the present invention, the magnetic field formed between the magnetic poles of the first and second rotating bodies can continuously provide a sufficient acceleration force to the non-magnetic metal, and the non-magnetic metal can be continuously applied. Since the rotation of the non-magnetic metal can be suppressed, it is possible to fly the non-magnetic metal far from the end of the transport path constituting body and efficiently separate it from other materials.

[Brief description of drawings]

FIG. 1 is a schematic view of a sorting apparatus according to the present invention.

FIG. 2 is an enlarged view of a main part of a sorting device.

[Explanation of symbols]

 3 ... Nonmagnetic metal 10x ... Conveyance path structure body 20 ... First rotating body 22 ... Motor (driving source) 30 ... Second rotating body

Claims (2)

[Scope of utility model registration request] 1. A non-metallic carrier path constructing body, and (b) a first rotating body which is disposed below an end of the carrier way constructing body and has different magnetic poles alternately arranged on the outer circumference. (C) The non-magnetic metal sorting apparatus further comprising: (c) a magnetic pole arranged differently from the upper surface of the transport path structure above the end of the transport path structure and having different magnetic poles alternately arranged on the outer periphery. A non-magnetic metal sorting device comprising a second rotating body that rotates so that magnetic poles different from the magnetic poles of the first rotating body face each other across the path forming body. 2. One of the first rotating body and the second rotating body is rotationally driven by a drive source, and the other rotating body is turned into one rotating body by magnetic attraction between magnetic poles of both rotating bodies. The non-magnetic metal sorting device according to claim 1, wherein the non-magnetic metal sorting device rotates together.