JP3533166B2 - Non-ferrous metal sorting machine - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a non-ferrous metal sorting machine for sorting non-ferrous metals from raw materials which are conveyed by a conveyor belt and which contain, for example, non-metallic and non-ferrous metals.

[0002]

2. Description of the Related Art Conventionally, a non-ferrous metal sorting machine for sorting non-ferrous metals from raw materials mixed with non-metals and non-ferrous metals is disclosed in, for example, Japanese Patent Publication No. 08-004759. There is a conveyor provided with a rotary magnet body inside a belt drum that guides a folded portion of a conveyor belt. The rotating magnet body is driven to rotate at a higher speed than the belt drum, the diameter of the rotating magnet body is smaller than that of the belt drum, and the rotating magnet body is arranged eccentrically with respect to the belt drum. In this case, in order to dispose the rotating magnet body inside the belt drum in an eccentric state, an arm that swingably supports the rotating shaft of the rotating magnet body from the center of the belt drum is provided, and the rotation that rotates at high speed is performed on the arm. It supports the magnet body.

[0003]

However, in the above-mentioned conventional non-ferrous metal sorter, the rotating magnet body rotating at high speed is
It is supported eccentrically inside the belt drum that rotates at a slower speed than the rotating magnet body, but inside the belt drum there is the rotation axis of the belt drum, and the belt drum is cylindrical, so the space is extremely small. Has become. Therefore, the rotating magnet body is rotatably supported by the arm, and the mounting structure of the arm that determines the installation angle of the arm and eccentrically fixes the rotating magnet body to a predetermined position is extremely complicated, and is installed inside the belt drum. Difficult to do,
Further, it is difficult to maintain the accuracy of the distance between the rotary magnet body and the inner side of the belt drum, and there is a problem that the equipment cost of the support mechanism of the rotary magnet body and the maintenance cost increase.
Further, since the arm is supported by the rotating shaft of the belt drum and the rotating magnet body is supported through the arm, it is difficult to give the supporting member of the rotating magnet body high rigidity,
There is a problem that vibrations and failures are likely to occur when the rotating magnet body rotates at high speed. The present invention has been made in view of such circumstances, and a supporting mechanism for a rotating magnet body provided with a permanent magnet and installation work are simple and inexpensive, and the rotating magnet body can be stably rotated at a high speed. The purpose is to provide a non-ferrous metal sorter.

[0004]

A non-ferrous metal separator according to the present invention, which is in accordance with the above object, has a rotating magnet body, which is rotated at a high speed with a gap between the conveyor belt and a curved portion, provided inside a curved portion of the conveyor belt. A non-ferrous metal sorter that sorts non-ferrous metal pieces from raw materials conveyed by a belt, the conveyor belt is wider than the width of the rotating magnet body, and both sides of the conveyor belt have a radius of curvature larger than the radius of the rotating magnet body. The rotary magnets are arranged on an arc and are supported by a plurality of guide rollers each having a diameter smaller than the diameter of the rotary magnet, and the rotary magnet is eccentrically arranged above the center of the radius of curvature of the curved portion. As a result, the curved portion of the folded portion of the conveyor belt is supported in a circular arc shape by the plurality of guide rollers, and the curved portion is not opened to the closed space like the cylindrical belt drum of the conventional example but opened to the inside. Since the formed space is formed, the guide roller can be supported by a support mechanism that is completely independent of the support mechanism of the rotating magnet body provided inside the curved portion. Therefore, since the rotating magnet body can form the supporting mechanism in the open space, the supporting mechanism of the rotating magnet body is very simple, the mounting work is easy, and the high speed rotation of the rotating magnet body is easy. Therefore, the distance between the rotating magnet body and the inside of the conveyor belt can be maintained, and the accuracy of selecting non-ferrous metal pieces can be improved.

Further, since the rotating magnet body rotating at a high speed is eccentric to the upper side of the center of the radius of curvature of the curved portion of the conveyor belt, the upper portion of the rotating magnet body is the portion where the straight portion of the conveyor belt transitions to the curved portion. The gap between the curved portion of the conveyor belt gradually increases as the distance from the upper portion of the rotary magnet decreases to the lower portion. Therefore, when the raw material is conveyed by the conveyor belt and reaches the curved portion, the non-ferrous metal piece in the raw material is subjected to the electromagnetic induction action of the moving magnetic field of the rotating magnet body that rotates at a high peripheral speed higher than the moving speed of the conveyor belt. Then, an induced current is generated in the non-ferrous metal piece, and due to the interaction between the moving magnetic field and the induced current, the thrust is applied in the rotating direction of the rotating magnet body, and the gravity and thrust of the non-ferrous metal piece are combined from the curved surface of the conveyor belt. Jump out in the direction of force. Since the non-metal piece in the raw material is not subjected to the electromagnetic induction effect of the moving magnetic field of the rotating magnet body, it falls downward from the curved portion of the conveyor belt due to the gravity of the non-metal piece. When iron pieces are mixed in the raw material, they are attracted to the moving magnetic field of the rotating magnet body and move on the surface of the curved portion of the conveyor belt. As the strength of the moving magnetic field becomes weaker and the attraction force becomes smaller than the gravity of the iron piece, it falls due to gravity. As described above, since the place where the non-ferrous metal piece, the non-metal piece, the iron piece, or the like falls from the curved portion of the conveyor belt is different, the non-ferrous metal piece can be selected from the raw material.

In the non-ferrous metal sorting machine according to the present invention, the rotating magnet body may be covered with a cylindrical non-magnetic metal member on the outer circumference. In this case, the rotating magnet body is formed in a structure in which permanent magnets made of a material having a high energy product such as ferrite magnets and rare earth magnets are attached to the outer periphery of the rotating drum, and N and S magnetic poles are alternately arranged in the circumferential direction. . Then, by covering the outer circumference of the permanent magnet with a cylindrical non-magnetic metal member such as stainless steel, for example, even if centrifugal force acts on the permanent magnet due to high speed rotation of about 1000 to 1800 rotations per minute, It is extremely safe because it does not pop out and get damaged and no induced current is generated.

In the non-ferrous metal sorting machine according to the present invention, the inside of both sides of the conveyor belt may be provided with protrusions which are engaged with the outer ends of the guide rollers. In this case, since the protruding portions on both inner sides of the conveyor belt are hooked by the outer ends of the guide rollers, the conveyor belt does not come off from the guide rollers, and the curved portions of the conveyor belt can be reliably guided by the guide rollers. it can. Further, by providing the protrusions on both inner sides of the conveyor belt, it is possible to increase the sectional modulus of the conveyor belt, increase the rigidity, and prevent deformation. In the non-ferrous metal sorting machine according to the present invention,
A pair of pressing rollers may be provided in each of the guide rollers arranged in the curved portion to sandwich the conveyor belt from inside and outside. In this case, since both sides of the curved portion of the conveyor belt in the belt width direction are sandwiched by the guide roller and the pressing roller, it is possible to reduce slack due to gravity of the raw material in the central portion of the conveyor belt, and the conveyor belt rotates at high speed. It does not come into contact with the rotating magnet body.

In the non-ferrous metal sorting machine according to the present invention, each guide roller arranged in the curved portion has a pair of guide rollers on opposite sides with respect to the traveling direction of the conveyor belt.
It may be opened toward the outside in the width direction at a slight angle so as to form an eight shape, and a pulling force in the width direction may be applied to the passing conveyor belt. In this case, since a tensile force is applied to the conveyor belt in the width direction, the central portion of the conveyor belt is not loosened, and a large amount of raw material can be stably conveyed.

[0009]

BEST MODE FOR CARRYING OUT THE INVENTION Next, referring to the attached drawings, an embodiment in which the present invention is embodied will be described to provide an understanding of the present invention. 1 is a side view of a non-ferrous metal sorting machine according to the first embodiment of the present invention, FIG. 2 is a sectional view of the same, and FIG. 3 is a non-ferrous metal sorting machine according to the second embodiment of the present invention. FIG. 4 is a side view of the machine, FIG. 4 is a sectional view of the same, and FIG.
FIG. 3 is a front view of a guide roller of the non-ferrous metal separator according to the embodiment of FIG.

As shown in FIGS. 1 and 2, the non-ferrous metal sorting machine 10 according to the first embodiment of the present invention includes a belt conveyor 11 extending in the carrying direction. At one end (end in the traveling direction) of the belt conveyor 11, head-side pedestals 12 arranged at intervals in the width direction are provided, and on the head-side pedestals 12, side-viewed half-moon shaped holders are provided. 1
3 is attached via the attaching member 13A, and the arcuate portion 14 on the outer periphery of the holder 13 is arranged so as to face outward (the traveling direction of the belt conveyor 11). The brackets 15 that extend radially are formed at equal intervals on the outer peripheries of both arc portions 14, that is, brackets 15 that extend in the vertical direction are attached to the outer peripheries of the arc portions 14 in pairs. The bracket 15 has a support shaft 16
A guide roller 17 rotatably supported on the support shaft 16
It is supported by both ends through. At the other end of the belt conveyor 11, there are provided tail side mounts 18 arranged at intervals in the width direction, and a tail pulley 21 having a pulley shaft 20 supported via bearings 19 on the tail side mounts 18.
Is provided. The tail pulley 21 is driven by the drive motor 24 via a sprocket 22 fixed to the pulley shaft 20, a chain 23, and a sprocket 25 fixed to the output shaft of the drive motor 24.

A plurality of guide rollers 17 and tail pulley 2
An endless conveyor belt 26 is wound around 1, and each part of the conveyor belt 26 that contacts a plurality of guide rollers 17 arranged in an arc forms a curved portion 27 having a predetermined radius of curvature continuously. The folded portion of the belt 26 is formed. Therefore, the inside of the curved portion 27 forms a space that is open to the inside, rather than the space that is closed like the cylindrical belt drum of the conventional example. Inside both sides of the conveyor belt 26 in the belt width direction (the side that contacts the guide roller 17 and the tail pulley 21)
Includes a protruding portion 29 that engages with the outer end of the guide roller 17.
Are provided over the entire length of the conveyor belt 26. Above the tail pulley 21 side of the conveyor belt 26, there is provided a chute 33 for supplying the raw material 32 including the non-metal piece 30 and the non-ferrous metal piece 31 onto the conveyor belt 26.
By rotating the tail pulley 21 by the drive motor 24, the conveyor belt 26 is moved, and the raw material 32 supplied onto the conveyor belt 26 from the chute 33 is moved.
Is conveyed to the guide roller 17 side at a speed of, for example, 20 to 80 m / min.

Inside the curved portion 27 of the conveyor belt 26, there is disposed a rotating magnet body 34 which rotates at a high speed with a gap provided between the inside and the inside of the conveyor belt 26. Rotating magnet body 34
Is the two side plates 3 fixed to the rotary shaft 35 with a space therebetween.
6 and a support drum 37 provided between the side plates 36, and both ends of the rotary shaft 35 are mounted on the head-side mount 12 by bearings 3.
8 through, for example 1000-1800 revolutions /
It is coupled via a coupling 39A to a drive motor 39 which is driven at a rotation speed of about one minute. The rotary shaft 35
Is a cutout portion 1 provided in the string portion of the half-moon shaped holding body 13.
It is designed to be loaded into 3B. Support drum 37
A permanent magnet 40 made of a magnetic material having a high energy product, such as a ferrite magnet or a rare earth magnet, is attached to the outer periphery of the magnet and is magnetized so that the N and S magnetic poles are alternately arranged in the circumferential direction. The outer circumference of the permanent magnet 40 is covered with a cylindrical non-magnetic metal member 41 such as stainless steel having a thickness of about 1 to 2 mm, and both sides thereof are firmly fixed to the side plates 36 by welding or the like, and the rotary magnet body 34 is The permanent magnet 40 is prevented from coming off from the supporting drum 37 and popping out by the centrifugal force when rotating at a high speed. In addition, since the non-magnetic metal member 41 does not generate an induced current, it is extremely safe. Further, the diameter D ₁ of the rotating magnet body 34 is determined by the guide roller 1
7 is larger than the diameter D _{2 of} the rotating magnet body 34 and has a radius R _{1 of the} rotating magnet body 34.
(D _1/2) is formed to be smaller than the radius of curvature R ₃ of the curved portion 27. The rotating magnet body 34 is arranged eccentrically above the center of the radius of curvature R ₃ of the bending portion 27, and the width B ₁ of the rotating magnet body 34 is formed narrower than the width B ₂ of the conveyor belt 26. It is arranged between the guide rollers 17 on both sides of.

Now, the operation of the non-ferrous metal separator 10 according to the first embodiment of the present invention will be described. First, the rotary magnet body 34 is rotated at a high speed of, for example, about 1000 to 1800 rotations / minute, and the tail pulley 21 is driven by the drive motor 24 via the sprocket 25, the chain 23, and the sprocket 22, and the upper portion of the conveyor belt 26. Is moved from the tail pulley 21 side to the guide roller 17 side. Next, when the raw material 32 including the non-metal piece 30 and the non-ferrous metal piece 31 is supplied from the chute 33 onto the conveyor belt 26, the raw material 32 is conveyed toward the guide roller 17 side, that is, the curved portion 27. In the curved portion 27, the protrusions 29 on both inner sides of the conveyor belt 26 are formed by the guide rollers 17
Since it is hooked on the outer end of the conveyor belt 26, the conveyor belt 26 does not come off the guide roller 17,
The curved portion 27 can be guided by the guide roller 17.

When the raw material 32 is conveyed by the conveyor belt 26 and approaches the curved portion 27, the non-ferrous metal pieces 31 in the raw material 32 move at a moving speed of the conveyor belt 26, for example, 20.
~ 80m / peripheral speed faster than about 1 minute (for example, 1000 ~ 1
It is subjected to the electromagnetic induction action of the moving magnetic field of the rotating magnet body 34 that rotates at a high speed of about 800 m / min. Then, the non-ferrous metal piece 31 generates an induced current inside and receives a thrust in the rotation direction of the rotating magnet body 34 due to the interaction of the moving magnetic field and the induced current, and the non-ferrous metal piece 31 is pushed from the surface of the curved portion 27 of the conveyor belt 26. It jumps out in the direction of the combined force of gravity and thrust of 31 and falls to a position away from the bending portion 27. Since the non-metal piece 30 in the raw material 32 is not subjected to the electromagnetic induction effect of the moving magnetic field of the rotating magnet body 34, the non-metal piece 30 falls downward from the curved portion 27 of the conveyor belt 26 due to the gravity of the non-metal piece 30. Raw material 32
When the iron piece 42 is mixed with the iron magnet 42, it is attracted by the moving magnetic field of the rotating magnet body 34 and moves together with the bending portion 27 of the conveyor belt 26.
Since the gap between the rotating magnet body 34 and the rotating magnet body 34 becomes large, the strength of the moving magnetic field becomes weaker, and the attraction force of the moving magnetic field becomes smaller than the gravity of the iron piece 42, so that it falls near the center of the rotating magnet body 34. Therefore, the moving magnetic field does not generate an eddy current in the iron piece 42 to generate heat, and the conveyor belt 26
No more damage to your. In this way, the raw material 32
The elements mixed in the non-ferrous metal piece 31, the non-metal piece 30, the iron piece 42, and the like are curved portions 2 of the conveyor belt 26.
Since the place where it falls from 7 differs, the non-ferrous metal piece 31 can be reliably separated from the raw material 32.

As shown in FIGS. 3 and 4, the non-ferrous metal separator 50 according to the second embodiment of the present invention is arranged on the curved portion 27 of the non-ferrous metal separator 10 according to the first embodiment. Each of the guide rollers 17 is provided with a pair of pressing rollers 51 so as to sandwich the curved portion 27 of the conveyor belt 26 from inside and outside. The same components as those of the non-ferrous metal separator 10 according to the first embodiment will be described with the same reference numerals. That is, the holding body 13 fixed to the head-side mount 12 is provided with the bracket 15 that supports the guide roller 17, and the holding plate 52 that extends radially outward from the arc portion 14 is provided at the same position as the bracket 15. The bracket 53 has a compression spring 54 and a holding rod 55 at the tip of the holding plate 52, respectively.
It is attached so as to be constantly pulled in the direction of the base portion of the holding plate 52 via. The bracket 53 supports the pressing roller 51, which is rotatably supported by the support shaft 56, on the support shaft 5.
6 is supported by both ends, and the pressing roller 51 is arranged so as to be paired with each guide roller 17, and the guide roller 17 and the pressing roller 51 are used to guide each other.
Both end portions in the belt width direction of the conveyor belt 26 wound around are clamped from the inside and the outside by the compression force of the compression spring 54. As a result, the conveyor belt 26 conveys the raw material 32 in a state where both ends are sandwiched by the guide roller 17 and the pressing roller 51, and further, the raw material 32 is conveyed while being pulled to both sides in the belt width direction. No slack in the part,
It does not come into contact with the rotating magnet body 34 that rotates at high speed.

As shown in FIG. 5, the non-ferrous metal sorter 60 according to the third embodiment of the present invention is arranged on each of the curved portions 27 of the non-ferrous metal sorter 10 according to the first embodiment. Of the guide roller 17 is opened at a slight angle with respect to the traveling direction of the conveyor belt 26, and the outside of the guide roller 17 is hooked on the protrusion 29 and passes through the conveyor belt 26.
It is designed to give a pulling force to the belt width direction. The non-ferrous metal sorter 1 according to the first embodiment
The same components as 0 will be described with the same reference numerals. That is, the brackets 61 are slightly attached to the holders 13 fixed to the head-side mounts 12 on both sides, for example, 1 to 1.
The guide rollers 17 are attached to each other at an angle A of about 5 degrees, and the guide rollers 17 are attached to the bracket 61 via the support shaft 16 so that the guide rollers 17 open at a slight angle with respect to the traveling direction of the conveyor belt 26. . In this case, since the outer peripheral surface of the guide roller 17 is slightly inclined outward and the outer side of the guide roller 17 is hooked on the projecting portion 29, the force by which the conveyor belt 26 presses the guide roller 17, that is, the guide roller 17. A component in the width direction due to the angle A is generated from the force that acts perpendicularly on the outer peripheral surface of 17, and the force that pulls the conveyor belt 26 in the width direction increases. Therefore, slack does not occur in the central portion of the conveyor belt 26, and a large amount of the raw material 32 can be stably conveyed.

Although the present invention has been described above with respect to the non-ferrous metal separator according to the above-mentioned embodiment, the present invention is not limited to the structure described in the above-mentioned embodiment, and the scope of the claims is not limited. It also includes other embodiments and modifications that are conceivable within the scope of the matters described in. For example, an arc having a radius of curvature larger than the radius R ₁ of the rotating magnet body 34 in which a plurality of guide rollers 17 are arranged is formed by a combination of arcs having a plurality of radii of curvature,
For example, the curved portion may be formed to approximate a part of an ellipse, and the curved portion may be formed to follow a curved line of a combination of arcs formed by a plurality of guide rollers.
Also, for the outer diameter of the guide roller, increase the diameter that contacts the center side of the conveyor belt (the inner diameter in the width direction) and decrease the diameter that contacts both sides of the conveyor belt (the outer diameter in the width direction). The guide roller may be formed in a tapered shape. Further, in the non-ferrous metal sorter according to the above-described embodiment, the example in which the guide roller and the pressing roller are supported by the bracket through the support shaft by both ends is described.
The guide roller and the pressing roller may be supported on the bracket by a cantilever via a support shaft. Further, each guide roller 17 arranged on the curved portion 27 is held not only by the traveling direction of the conveyor belt 26 but also by a bracket so as to open at a slight angle with respect to a plane perpendicular to the surface of the conveyor belt 26. It may be held by the body.

[0018]

In the non-ferrous metal sorter according to claims 1 to 5, the width of the conveyor belt is wider than the width of the rotating magnet body, and both sides in the width direction of the conveyor belt are larger than the radius of the rotating magnet body. Since the rotary magnets are arranged on an arc having a radius of curvature and are respectively supported by a plurality of guide rollers having a diameter smaller than that of the rotary magnet body, the rotary magnet body is eccentrically arranged above the center of the radius of curvature of the curved portion. ,
The curved portion of the conveyor belt is not a space closed inside like the cylindrical belt drum of the conventional example, but an open space is formed inside, and the guide roller is provided inside the curved portion to support the rotating magnet body. It can be supported by a support mechanism completely independent of the mechanism. Also, since the rotating magnet body can form the supporting mechanism in the open space, the supporting mechanism of the rotating magnet body is extremely simple, the installation work is easy, the cost is low, and the rotating magnet body is High-speed rotation becomes easy, and the space between the rotating magnet body and the inside of the conveyor belt can be maintained,
The accuracy of sorting non-ferrous metals can be improved.

Particularly, in the non-ferrous metal sorter according to claim 2, since the outer periphery of the rotating magnet body is covered with the cylindrical non-magnetic metal member, the rotating magnet body rotates at a high speed and becomes a large permanent magnet. Even if a force is applied, the permanent magnet does not jump out of the rotary magnet body and is damaged, and no induced current is generated, which is extremely safe. Claim 3
In the non-ferrous metal sorter described, the inner side in the width direction of the conveyor belt on both sides in the radial direction is provided with the protrusions that engage with the widthwise outer ends of the guide rollers, so that the conveyor belt is disengaged from the guide rollers. Therefore, the curved portion of the conveyor belt can be reliably guided by the guide roller.

In the non-ferrous metal sorter according to claim 4, each of the guide rollers arranged in the curved portion has:
Since a pair of pressure rollers is provided and the conveyor belt is sandwiched from the inside and outside, it is possible to reduce the slack due to the gravity of the raw material in the central portion of the conveyor belt,
Since the conveyor belt does not come into contact with the rotating magnet body that rotates at high speed, the conveyor belt can be driven extremely safely. In the non-ferrous metal sorter according to claim 5, each of the guide rollers arranged in the curved portion is
It opens at a slight angle outward in the width direction with respect to the direction of travel of the conveyor belt, and is designed to apply a pulling force in the width direction to the passing conveyor belt, so there is no slack in the center of the conveyor belt. Therefore, it becomes possible to stably convey a large amount of raw material.

[Brief description of drawings]

FIG. 1 is a side view of a non-ferrous metal sorter according to a first embodiment of the present invention.

FIG. 2 is a front sectional view of the same.

FIG. 3 is a side view of a non-ferrous metal separator according to a second embodiment of the present invention.

FIG. 4 is a front sectional view of the same.

FIG. 5 is a front view of a guide roller of a non-ferrous metal sorting machine according to a third embodiment of the present invention.

[Explanation of symbols]

10: Non-ferrous metal sorter, 11: Belt conveyor, 12:
Head side mount, 13: holding body, 13A: mounting member, 1
3B: cutout portion, 14: arc portion, 15: bracket,
16: support shaft, 17: guide roller, 18: tail side mount, 19: bearing, 20: pulley shaft, 21: tail pulley, 22: sprocket, 23: chain, 24: drive motor, 25: sprocket, 26: conveyor belt ,
27: curved portion, 29: protruding portion, 30: non-metal piece, 31:
Non-ferrous metal piece, 32: raw material, 33: chute, 34: rotating magnet body, 35: rotating shaft, 36: side plate, 37: support drum, 38: bearing, 39: drive motor, 39A: coupling, 40: permanent magnet , 41: non-magnetic metal member, 42:
Iron piece, 50: Non-ferrous metal sorter, 51: Pressing roller, 5
2: holding plate, 53: bracket, 54: compression spring, 5
5: Holding rod, 56: Support shaft, 60: Non-ferrous metal sorter, 61: Bracket

Claims (5)

(57) [Claims] 1. A non-ferrous metal sorter for sorting a non-ferrous metal piece from a raw material conveyed by the conveyor belt by disposing a rotating magnet body that rotates at a high speed inside the curved portion of the conveyor belt with a gap provided between the conveyor belt and the conveyor belt. In the machine, the width of the conveyor belt is wider than the width of the rotating magnet body, both sides in the width direction of the conveyor belt are arranged on an arc having a radius of curvature larger than the radius of the rotating magnet body,
Moreover, each of the rotating magnet bodies is supported by a plurality of guide rollers having a diameter smaller than that of the rotating magnet body, and the rotating magnet body is eccentrically arranged above the center of the radius of curvature of the curved portion. Sorting machine. 2. The non-ferrous metal sorter according to claim 1, wherein the rotating magnet body has an outer circumference covered with a cylindrical non-magnetic metal member. 3. The non-ferrous metal sorter according to claim 1, wherein protrusions are provided on both sides in the width direction of the conveyor belt inward in the radial direction, the protrusions engaging with outer ends in the width direction of the guide roller. A non-ferrous metal sorter that is characterized by 4. The non-ferrous metal sorting machine according to claim 1, wherein each guide roller arranged in the curved portion is provided with a pair of pressure rollers, and the conveyor belt A non-ferrous metal sorter characterized by being pinched from inside and outside. 5. The non-ferrous metal sorting machine according to claim 1, wherein each guide roller arranged in the curved portion has a pair of opposite guide rollers in an inverted eight shape.
The non-ferrous metal sorter is characterized in that the conveyor belt passing therethrough is opened at a slight angle toward the outside in the width direction so as to apply a pulling force in the width direction to the passing conveyor belt.