KR20210060774A - Nonferrous metal screening system using eddy current. - Google Patents

Abstract

The present invention provides a nonferrous metal screening system using an eddy current to easily perform classification by changing the strength the eddy current. According to the present invention, the nonferrous metal screening system comprises: a pulverizing means (100) crushing and pulverizing waste electrical and electronic products; and an eddy current changing means (200) capable of adding an eddy current to pulverized scrap pulverized and supplied by the pulverizing means and changing the strength of the eddy current applied to the pulverizing scrap. The eddy current changing means (200) includes a magnetic force generating means (300) generating a magnetic field to add the eddy current to the pulverized scrap to be classified and a conveyor device (400) transferring the pulverized scrap and providing a moving speed to the pulverized scrap. The magnetic force generating means (300) and the conveyor device (400) are provided separately from each other. The conveyor device (400) includes a rear roller (410), a conveyor belt (420), and a classification roller (430) installed at the end of the conveyor device (400). The magnetic force generating means (300) includes a magnet roll (310) generating the eddy current in the pulverized scrap.

Description

Nonferrous metal screening system using eddy current.}

The present invention is a non-ferrous metal sorting device using an eddy current, and more specifically, a crushing means for crushing and pulverizing electronic products to recover non-ferrous metals from waste electrical and electronic products, and eddy current to the crushing scrap supplied by crushing by the crushing means. A device for classifying non-ferrous metals by component by adding to, and to a non-ferrous metal sorting apparatus and classification method using an eddy current provided with an eddy current changing means capable of changing the intensity of the eddy current added to the crushed scrap.

In general, copper (Cu) wires are commonly used for waste wires or waste electrical and electronic products (waste motors), but aluminum (Al) with high conductivity is used in high voltage applications, and various types such as steel are used in cases, etc. Metals are used in, and iron materials are easily classified using magnetic force in ordinary scrap metal products, but non-ferrous metals are not classified in a classification device using ordinary magnetic force.

In order to recycle such waste wires or waste electrical and electronic products (waste motors), the powder or granular material crushed through a crushing process can be easily classified into metals and non-ferrous metals by using magnetic force, but non-ferrous metals are classified by ordinary magnetic force. As for the permanent magnet, the sorting operation is not easy, so the non-ferrous metal sorting device using eddy current is used for sorting.

Such a non-ferrous metal sorting device is known as "a sorting device in which non-magnetic metals can classify aluminum or aluminum alloys" in Korean Patent Laid-Open Publication No. 10-1996-0017471 (published on June 17, 1996).

1 shows a non-ferrous metal sorting device using an eddy current of the prior art, and looking at the non-ferrous metal sorting device, a permanent magnet inside the rotary roller 22 rotates by contacting the conveyor belt at the end of the conveyor belt 20 A configuration in which 28 is inserted and rotated by the rotation shaft 12 is shown.

In addition, referring to FIG. 2, it can be seen that the non-ferrous metal sorting apparatus of the prior art has a permanent magnet inserted into the rotary roller 22 of the conveyor belt and rotates at a constant speed in the same direction as the conveyor belt.

When the permanent magnet 28 rotates, an eddy current is generated in the non-ferrous metal moving while the non-ferrous metal being transferred to the upper part is moved, and the non-ferrous metal being transferred by the eddy current generates a force opposite to the moving direction.

In this way, a difference occurs in the force opposite to the direction of movement according to the components of the non-ferrous metal being moved, and the drop point is also different due to the inertia according to the gravity of the non-ferrous metal and the conveying speed of the conveyor belt.

In order to increase the discrimination power of non-ferrous metals according to this principle, referring to FIG. 3 for eddy current, an eddy current (渦電流) generated by a research magnet generates an electromotive force when the magnetic flux changes in a magnetic body. Among them, as shown in FIG. 3, a swirl-shaped current flows, and the swirl-shaped current is referred to as an eddy current. [Naver Encyclopedia of Knowledge]

Therefore, in order to increase the eddy current, there is a method of increasing the magnetic flux applied to the magnetic material or increasing the moving speed of the magnetic material.

In order to increase the magnetic force of the permanent magnet or increase the difference in the transfer speed between the non-ferrous metal powder and granular material and the permanent magnet by increasing the intensity of the eddy current in the non-ferrous metal powder or grain loaded on the top of the prior art conveyor belt shown in FIGS. 1 and 2 Although it is necessary to increase the number of rotations of the rotary roller, there is a problem that the conveying speed of the conveyor belt is also increased when the number of rotations of the rotary roller is increased.

1): Korean Patent Application Publication No. 10-1996-0017471 2): Korean Patent Application Publication No. 10-2014-0116571 3): Korean Patent Publication No. 10-0349175 4): Korean Patent Publication No. 10-1748434

The present invention is to solve the above-described problem, and comprises a pulverizing means for crushing and crushing a waste electric wire or a waste electric and electronic product (waste motor), and a non-metallic component such as synthetic resin contained in the crushing scrap pulverized by the pulverizing means. Classification by using an eddy current classifier so that the classification of non-ferrous metals and non-ferrous metals can be performed at the same time, but the non-ferrous metals that can change the intensity of the eddy current by changing the rate of change of magnetic flux according to the type of mixture of non-metals to be classified Its purpose is to provide a device.

In addition, as a structure capable of changing the strength of the eddy current, a sorting roller is installed at the end of the conveyor device that transports the crushed scrap to generate an eddy current in the crushed scrap that is moved up and down on the upper conveyor belt of the sorting roller.

The eddy current is arranged using a magnetic roll so that it can rotate inside the sorting roller, and the magnetic roll and the sorting roller are separated from each other and arranged,

The purpose of changing the intensity of the eddy current is to provide a non-ferrous metal sorting device capable of changing the rotational speed of the sorting roller and/or the rotational speed of the magnetic roll.

The present invention is to solve the above-described problems, a crushing means 100 for crushing and crushing waste electrical and electronic products, and adding an eddy current to the crushing scrap supplied by crushing by the crushing means, which is added to the crushing scrap. There is provided a non-ferrous metal sorting apparatus using an eddy current, characterized in that the eddy current changing means 200 capable of changing the intensity of the eddy current is provided.

Preferably, the eddy current changing means 200 includes a magnetic force generating means 300 generating a magnetic field in order to add an eddy current to the crushed scraps, and a conveyor that transports the crushed scraps and provides a moving speed to the crushed scraps. It is formed of a device 400, the magnetic force generating means 300 and the conveyor device 400 are provided separately from each other,

The conveyor device 400 is provided with a rear roller 410, a conveyor belt 420, a sorting roller 430 installed at the end of the conveyor device 400, and the magnetic force generating means 300 is the crushing scrap It includes a magnet roll 310 to generate an eddy current.

In addition, the magnet roll 310 is disposed so as to be rotated inside the sorting roller 430 and is disposed to be separated from the sorting roller, and the driving means of the conveyor belt 420 and the magnetic roll 310 The driving means of is provided separately, and the strength of the eddy current generated in the crushing scrap is changed by the rotational speed of the sorting roller and/or the rotational speed of the magnetic roll.

In addition, the intensity of the eddy current generated in the crushing scrap is changed by making the rotation direction of the sorting roller and the rotation direction of the magnetic roll the same or different from each other, and the driving means of the conveyor belt 420 and the magnetic roll ( 310) and a controller for controlling the driving means, and the controller 330 changes the conveying speed of the conveyor belt 420 of the conveyor device 400 or/and the magnetic roll 310 according to the type of the crushing scrap. ) By adjusting the rotational direction and rotational speed of the crushing scrap by changing the conveying speed of the conveyor and the relative speed of the magnetic roll, thereby controlling the intensity of the eddy current generated in the crushing scrap.

In addition, in order to select copper (Cu) and aluminum (Al) from non-ferrous metals in the crushing scrap, the conveying speed of the conveyor belt 420 is limited to 0.5 m/s or less,

Conveyor belt 510 rotated in contact with the upper surface of the sorting roller 430 of the conveyor device by rotating the rotation direction of the magnet roll 310 at 500 to 600 rpm in the direction opposite to the rotation direction of the conveyor belt 510 ) Classify by forming a magnetic force of 4,000 to 10,000 gauss on the surface.

In addition, the number of magnetic poles 621 of the magnetic roll 310 is 10 to 15, the magnetic field strength of the magnetic roll 310 is formed to 5,000 to 10,000 gauss, the magnet roll 310 is neodymium (Nd) Neodymium magnets, which are added permanent magnets, are used.

In addition, the crushed scrap is regularly cut to a length of 2 to 5 mm, and the loading height of the crushed scrap loaded on the conveyor belt 510 is loaded to 5 mm or less.

In addition, the crushing means 100 includes a primary crusher 110 for crushing the waste electrical and electronic products, and magnetic scrap (metal) and nonmagnetic material included in the crushed scrap by transporting the crushed scrap crushed by the first crushing machine. A magnetic sorting machine 120 for separating into scraps and a secondary grinding machine 130 for secondary pulverizing the nonmagnetic scrap separated in the magnetic sorting process.

As described above, according to the present invention, a crushing means for crushing and crushing a waste electric wire or a waste electrical and electronic product (waste motor) is provided, and according to the mixing type of the non-metal contained in the crushing scrap crushed by the crushing means, By changing the speed of change of the magnetic flux, the intensity of the eddy current can be changed, so that it can be easily classified into non-metal components such as synthetic resins and non-ferrous metals.

In addition, a sorting roller is installed at the end of the conveyor device that transports the crushed scrap to generate an eddy current in the crushed scrap that is moved up and down on the upper conveyor belt of the sorting roller, and the eddy current is a magnetic roll so that it can rotate inside the sorting roller. And the magnetic roll and the sorting roller are arranged to be separated from each other, so that the rotational speed of the sorting roller and/or the rotational speed of the magnetic roll can be changed to change the intensity of the eddy current. There is an effect of improving work efficiency by changing the intensity of the eddy current according to the type.

In addition, the magnetic roll has an effect of increasing the strength of the magnetic field compared to the volume of the magnetic roll by using a neodymium magnet, which is a permanent magnet to which neodymium (Nd) is added.

1 is a front view of a conventional eddy current classification device.
Figure 2 is a eddy current generation unit of the conventional eddy current classification device.
3 is a diagram showing the principle of generating an eddy current used in the present invention.
Figure 4 is a front view showing a non-ferrous metal sorting device using an eddy current according to an embodiment of the present invention.
Figure 5 is a cross-sectional view of a sorting roller installed at the end of the conveyor device according to a preferred embodiment of the present invention.
6 is a cross-sectional view of a magnet roll according to a preferred embodiment of the present invention.
Figure 7 is a schematic diagram of the manufacturing procedure of the grinding scrap classified in a preferred embodiment of the present invention.
Figure 8 is a photograph of a crushed scrap according to an embodiment of the present invention.
9 is an enlarged photograph of a crushed scrap according to an embodiment of the present invention.
10 is a waste resource recovery process chart classified in a preferred embodiment of the present invention.

As for terms used in the present invention, general terms that are currently widely used are selected, but in certain cases, some terms are arbitrarily selected by the applicant. In this case, the meanings described or used in the specific contents for carrying out the invention are not just the names of terms. The meaning should be understood by considering

Hereinafter, the technical configuration of the present invention will be described in detail with reference to preferred embodiments shown in the accompanying drawings. Here, it should be noted that all expressions related to directions such as up, down, left and right, right, left, and bottom are described based on the presented drawings.

The present invention may be implemented in various different forms and is not limited to the embodiments described herein. Like reference numerals are attached to similar parts throughout the specification.

In the accompanying Figure 4 shows a non-ferrous metal sorting apparatus using an eddy current according to an embodiment of the present invention,

The non-ferrous metal sorting apparatus using the eddy current of the present invention is provided with an eddy current changing means 200 capable of adding an eddy current to the crushed scrap to be classified, and changing the intensity of the eddy current added to the crushed scrap.

The eddy current changing means 200 includes a magnetic force generating means 300 for generating a magnetic field in order to add an eddy current to the crushed scraps to be classified, and a conveyor device 400 for transferring the crushed scraps and providing a moving speed to the crushed scraps. ), and the magnetic force generating means 300 and the conveyor device 400 are provided separately from each other.

In addition, the conveyor device 400 may be provided with a plurality of rollers for transferring the conveyor belt 420 and the conveyor belt 420 or preventing the conveyor belt 420 from sagging or separating, and a rear roller 410 and a sorting roller 430 installed at the end of the conveyor device 400 are provided.

In addition, the magnetic force generating means 300 includes a magnetic roll 310 for generating an eddy current in the crushing scrap.

In addition, the magnet roll 310 is disposed so as to be rotated inside the sorting roller 430 and is disposed to be separated from the sorting roller.

By separating and disposing the sorting roller 430 and the magnetic roll 310 in this way, the magnetic roll 310 is separated from the conveying device of the conveyor belt 420, so that the driving means of the conveyor belt 420 and the The driving means of the magnet roll 310 is provided separately.

In addition, a controller for controlling the driving means of the conveyor belt 420 and the driving means of the magnetic roll 310 is provided, and the controller 330 is a conveyor belt of the conveyor device 400 according to the type of the crushing scrap. By changing the feed speed of 420 or/and adjusting the rotation direction and rotation speed of the magnet roll 310, the feed speed of the crushing scrap conveyor and the relative speed of the magnet roll can be widely adjusted.

That is, as described above, the driving means of the conveyor belt 420 and the driving means of the magnetic roll 310 are separately provided, and the driving means of the conveyor belt 420 and the driving means of the magnetic roll 310 are controlled. As a controller is provided, even if the driving means of the conveyor belt 420 and the driving means of the magnet roll 310 rotate at the same rotational speed, when rotating in the same rotational direction, the sorting roller 430 of the conveyor belt and the The magnetic roll 310 rotates at the same speed, so that the difference in rotation speed between the two rollers 430 and 310 is "0", but the number of poles and the number of poles of the magnetic roll 310 inside the sorting roller 430 and rotating at the top Eddy current is generated weakly by the speed of the conveyor belt 420.

In addition, even when rotating at the same rotational speed as described above, if the rotational directions of the driving means of the conveyor belt 420 and the driving means of the magnetic roll 310 are rotated in opposite directions, the conveying speed of the conveyor belt 420 is increased. The speed transferred from the outer circumferential surface of the magnet roll 310 is added and doubled.

As suggested above, in order to decrease the relative conveying speed, when rotating in the same direction, it can proceed at a very low conveying speed. On the other hand, in order to use a relatively high conveying speed, the rotating direction of the magnetic roll is the progress of the conveyor belt 420. It rotates in the opposite direction to the direction, and the transfer speed can be adjusted in various ways by adjusting the rotation speed.

Although the eddy current has been described above, again, when the copper wire through which the magnetic force line passes on the conveyor belt 420 installed on the magnetic roll 310 is laid in a plane, the copper wire is the N-pole and the S of the magnetic roll. When positioned between the poles, the magnetic line of force of the magnet comes out of N, passes through the copper wire, turns back through the copper wire and enters S, and the electromotive force repeatedly flows in the clockwise direction by the rotation of the magnet roll 310. Since the S pole is formed and the N pole is made under the copper wire, the copper wire is repelled to the N pole of the magnet and is attracted to the S pole of the magnet, and a force opposite to the moving direction is generated. As the belt rotates in a state that bounces in the conveying direction, it falls to the position of the box B a little further away from the sorting roller 430 by the conveying speed of the conveyor belt and the repulsive force by the eddy current due to the specific gravity.

In addition, in the case of aluminum (Al), the conduction rate is lower than that of copper, so the eddy current is relatively lower than that of copper, and the specific gravity is relatively low compared to copper (Cu). It falls to the location of the box.

According to this configuration and principle, it is possible to classify according to the component by the difference in the electromotive force generated by the component of the non-ferrous metal and the difference in the specific gravity by the component of the non-ferrous metal.

In the present invention, in order to increase the selection rate of copper (Cu) and aluminum (Al) among non-ferrous metals in the crushing scrap, the conveying speed of the conveyor belt 420 is limited to 0.5 m/s or less, and the magnetic roll 310 4,000 to 10,000 gauss on the surface of the conveyor belt 510 rotated in contact with the upper surface of the sorting roller 430 of the conveyor device by rotating the rotation direction at 500 to 600 rpm in the direction opposite to the rotation direction of the conveyor belt 510 It is characterized in that to form a magnetic force.

In the above, the conveying speed of the conveyor belt 420 is limited to 0.5 m/s or less in consideration of the difference in the specific gravity of the copper (Cu) and aluminum (Al).

When the conveying speed is 0.5m/s or more, when the centrifugal force increases when the crushing scrap loaded and transported on the conveyor belt 420 from the top of the sorting roller 430 freely falls, the eddy current is generated in non-ferrous metals with a small amount. Since the free fall point by the repulsive force caused by the eddy current falls similarly, a problem occurs in the sorting operation, and the conveying speed of the conveyor belt 420 is limited to 0.5 m/s or less.

In addition, by rotating the rotation direction of the magnet roll 310 at 500 to 600 rpm in a direction opposite to the rotation direction of the conveyor belt 510, the magnet roll 310 and the conveyor belt 510 move in the same direction. Compared to rotation, a relatively high difference in movement speed occurs. Due to this difference in movement speed, 4,000 to 10,000 gauss on the surface of the conveyor belt 510 rotated in contact with the upper surface of the sorting roller 430 of the conveyor device. It is characterized in that to form a magnetic force.

5 and 6 are cross-sectional views of a sorting roller and a magnet roll installed at the end of a conveyor device according to a preferred embodiment of the present invention, and referring to this,

The number of magnetic poles 621 of the magnetic roll 310 is limited to 10 to 15, and when the number of magnetic poles is 15 or more, it may help to form a magnetic field, but the magnetic poles inserted into the magnetic rolls themselves have a relatively small volume. Since it can be a problem in durability performance, the optimal number of stimulations is limited to 10 to 15.

In addition, the magnetic field strength of the magnet roll 310 is formed to 5,000 to 10,000 gauss, and the strength of the magnetic field can be lowered when the number of magnetic poles is increased, but the magnetic field strength is limited to 15 or less depending on the relationship of the durability performance. The magnetic field strength should be at least 10,000 gauss or more to have at least 5,000 gauss, and the magnetic field strength should be at least 10,000 gauss for the cost, and the magnetic field strength should be less than 10,000 gauss (Nd Neodymium magnets, which are permanent magnets with) added, are used.

By this numerical limitation, it is possible to effectively classify copper or aluminum components having a uniform size of at least 2mm or more of the particle length of nonferrous metals.

That is, if the particle size is too small to be 2 mm or less during the selection process of non-ferrous metals, the selection force by the magnetic line of force decreases remarkably, so the minimum particle size is preferably 2 mm or more. Most importantly, although the size of the copper or aluminum nonferrous metal is uniform, it is possible to select by eddy current. When the particle size of the nonferrous metal obtained through chipping is uneven, it is impossible to select copper or aluminum. In order to prevent this, it is most important to prepare grinding conditions so that non-ferrous metals such as copper or aluminum have a uniform particle size during crushing or grinding. For this, the shape of the crushing blade and the moving speed of the conveyor during crushing, the classification speed, and the rotation speed are of paramount importance.

Secondly, even if a uniform fine particle nonferrous metal is obtained, it must be transported in a thin thickness of the laminated nonferrous metal when moving the conveyor using an eddy current. When a large number of non-ferrous metal particles accumulate to form a thick layer and move on a conveyor, even if the magnetic force is affected by the eddy current, it is limited to only a part of the area, making it difficult to sort out a large number of non-ferrous metal particles. Therefore, it is of utmost importance to control the moving speed and classification speed so that the conveyor can be moved in an appropriate amount during classification.

In addition, in order to effectively separate these non-ferrous metal powders and grains, the loading thickness of the crushed scrap that is loaded and transported on the conveyor belt 420 must be made of one to two layers of moving crushed scrap particles so that eddy current can be uniformly generated. , It is easy for classification to have a thickness of about one or two of the pulverized particles.

Referring to Figure 6, looking at the process of the crushing scrap classified in the non-ferrous metal sorting apparatus using the eddy current of the present invention, the coil of the raw material, the coil of the motor and the waste wire can be uniformly cut (Chopping) through stripping and crushing process.

8 shows a process for automating the above process,

Received waste resources are transferred to a crusher by a belt conveyor, crushed first, and transferred to a crusher. Then, the crusher is subjected to secondary pulverization to complete a crushed scrap classified into a certain length.

This means that the crushing means 100 transports the crushed scraps crushed by the primary crushers 110 and the crushed scraps by the primary crushers to crush the waste electrical and electronic products, and magnetic scraps (metals) and non-magnetic scraps included in the crushed scraps. It consists of a magnetic sorting machine 120 for separating into, and a secondary crusher 130 for secondary grinding the nonmagnetic scrap separated in the magnetic sorting process.

In Figures 9 and 10, the crushed scrap produced in this way as a photograph of a crushed scrap according to a preferred embodiment and an enlarged photograph is a constant length of 2 to 5 mm in order to be easily classified by a non-ferrous metal sorting device using an eddy current. It is cut (Chopping), and according to this length, the eddy current is easily generated and classified in the crushed scrap when the loading height of the crushed scrap loaded on the conveyor belt 510 is loaded to 5 mm or less.

The above description is an illustrative description of the present invention, and the embodiments published in the specification are not intended to limit the technical idea of the present invention, but to explain the present invention. Various modifications and variations will be possible without departing from the technical idea of Therefore, the scope of protection of the present invention is interpreted by the matters described in the claims, and technical matters within the scope equivalent thereto are to be construed as being included in the scope of the present invention.

100: grinding means 200: vortex change means
300: magnetic force generating means 310: magnet roll
320: magnetic roll driving means 330: controller
400: conveyor device 410: rear roller
420: conveyor belt 430: sorting roller

Claims (9)

Crushing means 100 for crushing and crushing waste electrical and electronic products, and
An eddy current is added to the crushed scrap supplied by crushing in the crushing means,
Non-ferrous metal sorting device using an eddy current, characterized in that the eddy current changing means (200) capable of changing the intensity of the eddy current added to the crushed scrap is provided. The method of claim 1,
The eddy current changing means 200 includes a magnetic force generating means 300 for generating a magnetic field in order to add an eddy current to the crushed scraps to be classified, and a conveyor device 400 for transferring the crushed scraps and providing a moving speed to the crushed scraps. ),
The magnetic force generating means (300) and the conveyor device (400) is a non-ferrous metal sorting device using an eddy current, characterized in that provided separately from each other. The method of claim 2,
The conveyor device 400 includes a rear roller 410 and a conveyor belt 420, and a sorting roller 430 installed at the end of the conveyor device 400,
The magnetic force generating means 300 comprises a magnetic roll 310 generating an eddy current in the crushing scrap. The method of claim 3
The magnet roll 310 is disposed so as to be rotated inside the sorting roller 430, and the non-ferrous metal sorting device using an eddy current, characterized in that the sorting roller and the sorting roller are separated from each other. The method of claim 4,
Non-ferrous metal sorting device using eddy current, characterized in that the drive means of the conveyor belt (420) and the drive means of the magnet roll (310) are provided separately. The method of claim 5,
The non-ferrous metal sorting apparatus using an eddy current, characterized in that the intensity of the eddy current generated in the crushing scrap is changed by the rotation speed of the sorting roller and/or the rotation speed of the magnet roll. The method of claim 5,
The non-ferrous metal sorting apparatus using an eddy current, characterized in that the intensity of the eddy current generated in the crushing scrap is changed by making the rotation direction of the sorting roller and the rotation direction of the magnet roll the same or different from each other. The method of claim 5,
And a controller for controlling the driving means of the conveyor belt 420 and the driving means of the magnetic roll 310,
The controller 330 is
Depending on the type of the crushing scrap, the crushing scrap and the conveying speed of the conveyor are adjusted by changing the conveying speed of the conveyor belt 420 of the conveyor device 400 or/and adjusting the rotational direction and the rotational speed of the magnetic roll 310. By changing the relative speed of the magnet roll
Non-ferrous metal sorting device using an eddy current, characterized in that formed to adjust the intensity of the eddy current generated in the crushed scrap. The method of claim 8,
In order to select copper (Cu) and aluminum (Al) among non-ferrous metals in the crushing scrap
The conveying speed of the conveyor belt 420 is limited to 0.5m/s or less,
By rotating the rotation direction of the magnet roll 310 in a direction opposite to the rotation direction of the conveyor belt 510 at 500 to 600 rpm,
Non-ferrous metal sorting device using an eddy current, characterized in that to form a magnetic force of 4,000 to 10,000 gauss on the surface of the conveyor belt 510 rotated in contact with the upper surface of the sorting roller 430 of the conveyor device.

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