JPH08192107A - Method for separating motor-core in shredded waste iron - Google Patents

Abstract

PURPOSE: To improve the removal rate of motor cores by directing air jet to falling shredded waste iron in a separation chamber installed in the discharge part of a conveyer for transporting shredded waste iron and sorting the waste into motor cores and iron components in the waste by wind force from the relation of the difference in air resistance. CONSTITUTION: A waste car 1 transported by a conveyer, etc., is crushed by a shredding machine 2 to be sorted into crushed waste iron and dust 35. Next, the crushed iron is sorted into magnetic waste iron and non-ferrous material 6 in a magnetic sorter 3, and the magnetic waste iron is sorted into motor cores 7 and iron components 8 in a motor core separator 4. In the separator 4, the waste iron supplied to a separator 11, in spontaneous falling from the end of a conveyer 9, is flown away by wind pressure by ejecting compressed air 18 from a blower 10 from a jet nozzle 17 so that the difference between the flight positions of separation 12a, 12b is produced by the weight difference for the separation.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention relates to shredder scraps for effectively recycling iron scraps for improving the separation and removal rate of motor cores as copper sources contained in shredder scraps of abandoned automobiles. The present invention relates to a motor core separation method.

[0002]

2. Description of the Related Art Generally, an abandoned vehicle is crushed by a shredder device, and the iron content in the crushed material is, for example, Japanese Patent Publication No.
As disclosed in the 8895 publication, a method of separating from other nonmagnetic mixture by a magnetic separator is known. However, the iron scraps separated by the conventional magnetic separator include the iron core of the motor used as various driving devices for automobiles and the core made of copper wire.
When the raw material is melted and used as an iron source, the copper wire of the motor core is melted, and it is currently difficult to remove the copper in the molten steel, so the copper concentration in the molten steel increases and the quality of the steel deteriorates. It is known to cause. Therefore, conventionally, the motor cores are visually selected on the conveyor line for transferring the iron scraps and manually separated. Approximately 500 kg from a single vehicle, depending on the type of vehicle scrapped
The iron content is recovered, but in one manual selection,
Includes about 4 motor cores.

[0003] As a result of recycling the iron from the shredder scrap of an abandoned motor vehicle which has 100% of the motor core removed and remelted in a steelmaking furnace, the copper concentration in the molten steel is about 0.06%. After the core is removed, the shredder scrap is remelted and the copper concentration in the molten steel is about 0.2.
It became%. The motor core is not completely removed and remains. As described above, conventionally, identification and separation were performed by one or two human hands, but there was a considerable problem in completely separating them. Basically, it is thought that the whole amount of motor core mixed in cannot be removed manually. On the other hand, the wind separation as a separation method is limited to the removal of plastic films and paper scraps from municipal waste and the classification of other objects such as wheat flour having a small solid weight, and has not been used in the field of iron scraps. In addition, although separation with water is also conceivable, there is a risk of steam explosion at the time of dissolution of the recovered iron scraps and the water remaining inside the iron scraps when dissolved in an electric furnace, a converter or the like. It is desired to solve the above problems and develop a technology for removing the entire motor core as a copper source from the shredder iron scrap.

[0004]

As described above, in the iron scrap processing step, the method of identifying and separating the motor core cannot be sufficiently separated by one or two human hands.
Even if the number of manpower is increased and the whole amount of the motor core is separated, about 10 people are required, which increases the cost and is not a realistic method. Further, if the copper concentration in the iron scraps to be recycled is increased, it is expected that the recycling rate of the iron scraps will have to be reduced. Therefore, it is necessary to improve the iron scrap recycling rate from the viewpoint of improving the global environment. An object of the present invention is to provide a method of removing the entire amount of the motor core from the shredder iron scraps in order to address the above conventional problems.

[0005]

The present invention is intended to solve the above-mentioned problems, and the gist thereof is as follows. (1) In shredder scraps separated by a magnetic sorter of a shredder device for crushing scrap cars In the motor core separation method, an air jet is blown against the shredder iron scraps that fall in the separation chamber provided in the discharge part of the conveyor that conveys the shredder iron scraps, and due to the difference in air resistance, A method for separating a motor core from shredder iron scrap, which comprises separating the motor core and the iron by wind force.

(2) The method for separating a motor core in shredder iron scrap as described in (1), wherein the air jet blows in the direction of the maximum projected area of each solid of the shredder iron scrap falling from the discharge part of the conveyor.

(3) The method of separating motor cores in shredder iron scrap as described in (1), wherein the air jet blows in a direction substantially perpendicular to the falling curve of the shredder iron scrap falling from the discharge part of the conveyor.

[0008]

Most of the shredder iron scraps are crushed iron plates of abandoned automobiles, the average size is about 50 mm, and the shape thereof is like a crumpled crushed iron plate. The weight of the simple substance is 100 to 700 g. Although each simple substance has various shapes, there is a lot of space inside and the apparent specific gravity of the solid is about 1 to ³ g / cm ³ although the true specific gravity of iron is about 7. In addition, most of them have a flat appearance, and it can be considered that the projected area on the plane is the largest when the single unit is placed on a flat surface, and the weight is divided by the projected area of each single unit. Value, that is, the weight per maximum projected area is about 1.3.
It was ~ 6.9 g / cm ² .

On the other hand, the motor core is a core portion in which the outer peripheral portion of the motor is broken and removed, and is composed of an iron core, a central core, and a copper wire. Since the motor core itself is strong and the size passes through the sieve of the shredder, most of the motor core is not crushed but mixed in the shredder iron scrap. The size is about the size of a hand glove or less, but the weight is 150 to 800 g
And it is almost the same as the iron plate. The motor core is substantially solid and has a bulk specific gravity of about 3.5 to 5.0 g / cm ³ . The weight per maximum projected area measured in the same manner was about 8.5 to 19.0 g / cm ² .

The present invention makes it possible to supply shredder scraps mixed with a motor core to a wind force separation chamber, blow an air jet, and sort by the difference in weight per maximum projected area. That is, an air jet is applied to the shredder iron scrap in the direction of the maximum projected area, and the iron component and the motor core are separated according to the flight distance. At this time, the shredder iron scraps dropped from the conveyor are accelerated in the air jet direction by receiving the resistance of the air jet in the air jet zone of a certain height. It has been found that the acceleration is proportional to the square of the velocity of the air jet and the area of the shredder iron scrap that receives the air jet, and is inversely proportional to the weight of the shredder iron scrap. That is, it means that the weight of the shredder iron scrap is divided by the projected area, in other words, the value is inversely proportional to the weight per unit projected area. Therefore, at the exit of the air jet zone,
The distance and the lateral speed of the shredder scraps beside the
It depends on the weight per unit projected area.
Iron, which has a small weight per unit projected area, is largely blown to the motor core, and the lateral velocity also becomes large. Further, as it falls, the distance that is blown in the lateral direction increases due to the difference in lateral speed between the two. In this way, since there is a difference in the weight per unit projected area of the iron scraps and the motor core in the shredder iron scraps, it is possible to easily separate them by this method.

At this time, when the shredder iron scraps are placed on the conveyor, it is necessary that each solid of the shredder iron scraps be dispersed. For example, a lumped shredder iron scrap may be dispersed by a vibrating feeder or the like, or a collision plate may be provided at a connecting portion of the conveyor to disperse the shredder scrap. INDUSTRIAL APPLICABILITY The present invention can greatly improve the conventional motor core separation efficiency of one or two people. Further, the equipment of the present invention is simple and small in scale, has few maintenance points, and uses little electric power. Further, in the present invention, the mixture of copper in the shredder iron scrap is significantly reduced, and the recycling utilization rate of the shredder iron scrap as an iron source is improved. Hereinafter, the present invention will be described in more detail based on examples.

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows a flow chart of an embodiment of a method for separating a motor core in shredder iron scrap of the present invention. In this figure, a scrap car 1 is conveyed by a conveyor or the like, supplied to a shredder machine 2, and shredded. At this time, the shredder machine 2 separates the crushed iron scraps and the dust 5 attracted to the exhaust system. Next, the crushed iron waste is conveyed to the magnetic separator 3, where the magnetic iron waste and the non-ferrous material 6 are separated.
Further, the magnetic iron scraps are supplied to the motor core separator 4 and separated into the motor core 7 and the iron component 8.

For comparison, a conventional flow is shown in FIGS. 4 and 5. FIG. 4 is a flow mainly corresponding to separation of the motor core and corresponding to FIG. 1 of the present embodiment. Figure 5
Is the entire flow, and the conventional flow will be described below with reference to FIG. The scrap car 1 is conveyed by the conveyor 9 and supplied to the shredder machine 2 to be crushed. At this time, the shredder machine 2 pulls the crushed iron scraps and the exhaust system to separate the dust 5 through the wet scrubber 25. At this time, the shredder machine 2 is a hammer type crusher, and the dust generated is mainly cotton, plastic, rubber or the like, which can be separated from the air. Next, the crushed iron scraps are conveyed to the magnetic separator 3 through the wid shifter 24, where the magnetic iron scraps and the non-ferrous scraps are separated. Further, the magnetic iron scraps are manually sorted to separate the iron core 8 in order to separate the motor core.

FIG. 1 of the present embodiment is the same as the conventional flow chart 4 shown in FIG.
It corresponds to the flow in which the hand selection 23 is replaced with the motor core separator 4. FIG. 2 shows details of the motor core separator 4 of FIG. 1 of the present embodiment and the flow of subsequent steps. The magnetically sorted shredder iron scraps 21 are supplied to the separation chamber 11 by the conveyor 9. The iron scraps supplied to the separation chamber 11 spontaneously drop from the leading end of the conveyor or the drop surface provided further. The iron scrap dropping surface may be a surface having any angle. In this case, compressed air is fed from the blower 10 to the air jet nozzle 17 with respect to the iron dust that naturally falls, and the air jet 1
Wind 8 against the free-falling curve perpendicularly or at right angles,
The wind pressure causes the iron scraps to fly. An enlarged view of this portion is shown in FIG. An air jet port 22 is provided near the lower part of the conveyor 9. At this time, it is desirable that the conveyor 9 and the air jet port 22 have substantially the same width. This is because the blast zone of the present invention corresponds to the area of this air jet 22. This air jet 18 is formed in the direction of the maximum projected area of each solid or in the direction perpendicular or perpendicular to the falling curve of the iron scraps, whereby the air jets 18 are conveyed on the conveyor 9 and shredded to the shredder scraps falling from the tip. An efficient blast is realized.

Then, due to the length of the flying distance, a difference occurs in the positions of the separating cells 12a and 12b which fall, and as a result, the separating cells are separated by the difference in weight per maximum projected area. That is, a large weight per maximum projected area falls and stays in the separation cell 12a near the air jet 18, and a small weight per maximum projected area falls and stays in the farther separation cell 12b. To do. That is, since the weight per maximum projected area of the motor core is considerably larger than the iron content, the motor core falls and stays only in the separation cell 12a in the vicinity of the air jet 18, which enables complete separation. . This flight trajectory is shown by reference numeral 19 in FIG. 2 as a motor core dropping surface and reference numeral 20 as an iron dropping surface.

In this case, iron having the same shape as the motor core and having a weight per maximum projected area of course enters the same separation cell, but this amount is extremely small. Further, the air in the separation chamber 11 is dirty and passes through the dust collector 15 to exhaust the air, and the used air is exhausted from the blower 10 and the exhaust tower 16. The dust collected by the dust collector 15 is processed as shredder dust. Then, the motor core and the iron content are carried out from the respective separation cells 12a and 12b by the iron content transfer path 13 and the motor cores transfer path 14, and at that time, the separated substances which have entered the separation cell having a high motor core mixing ratio are separated as motor core scraps. To be done.

The separation chamber 11 of this embodiment need not be sealed, but preferably has a lining at least to prevent noise. The separation result of this example will be described below. Table 2 shows the results of separation of shredder iron scraps by the separation chamber treatment of the present invention and manual selection as a comparative example under the separation conditions of Table 1. In addition, in Table 2, the waste car from which the engine, the battery, the tire, and the oil have been removed is shredded, and the shredder iron scrap magnetically separated is targeted.

[0018]

[Table 1]

[0019]

[Table 2]

From the separation conditions in Table 1 and the separation results in Table 2 of this example, it is understood that the flight distance between the iron component and the motor core can be completely separated by the method of the present invention. That is, the separation cell in the lower part of the separation chamber could be completely separated by providing a cell partition at a position 1.2 m from the position immediately below the conveyor. In the present embodiment, if the weight of the iron scraps per maximum projected area is relatively small, the iron scraps may fly about 7 m and may be mixed due to rebound. Therefore, as the device, it is preferable that the wall surface of the separation chamber on the air jet collision side is inclined downward. More preferably, the depth distance of the separation chamber can be set to about 2 to 3 m by adopting other means in which the iron scraps bounced off on the wall surface do not enter the separation cell of the motor core.

The present example in Table 2 shows the results when the processing amount and the vehicle type were the same in the present invention and the comparative example. The present invention shows an improvement in the number of recovered motor cores by 4 and a weight ratio of 48% in comparison with the comparative example, and it can be seen that the wind separation according to the present invention exhibits the effect of recovering the entire amount of the motor cores.

[0022]

As is apparent from the above embodiments, the present invention enables the shredder iron scraps to be separated by the wind force and the motor core to be almost completely removed. Greatly improves the separation rate of the motor core. Further, the equipment of the present invention is simple and small in scale, has few equipment maintenance points, and uses little electric power. further,
Copper content in shredder scrap is greatly reduced, and the recycling rate of shredder scrap as an iron source is increased. In addition, the present method can be replaced with a dust separating device in a shredder machine, and separation of the motor core can be performed. Further, when a lower degree of separation between iron and the motor core is allowed, it is possible to further reduce the size of the device and alleviate restrictions on the direction of the air jet blast.

[Brief description of drawings]

FIG. 1 is a diagram showing a separation flow of shredder iron scraps according to the present invention.

FIG. 2 is a diagram showing an outline of a wind power separation flow in a separation chamber according to the present invention.

FIG. 3 is a diagram showing an outline of an air jet port according to the present invention.

FIG. 4 is a diagram showing a flow of separating shredder iron scraps according to a conventional method.

FIG. 5 is a diagram showing a crushing and classification flow of scrapped vehicle scrap according to a conventional method.

[Explanation of symbols]

 1 ... Junk car 2 ... Shredder machine 3 ... Magnetic sorter 4 ... Motor core separator 5 ... Dust 6 ... Non-ferrous material 7 ... Motor core 8 ... Iron 9 ... Conveyor 10 ... Blower 11 ... Separation chamber 12a, 12b ... Separation cell 13 ... Iron transport path 14 ... Motor cores transport path 15 ... Dust collector 16 ... Exhaust tower 17 ... Air jet nozzle 18 ... Air jet 19 ... Motor core drop surface 20 ... Iron drop surface 21 ... Shredder iron scrap 22 ... Air jet port 23 ... Hand Sorting 24 ... Wind shifter 25 ... Wet scrubber

Claims (3)

[Claims] 1. A method for separating a motor core of shredder iron scraps separated by a magnetic separator of a shredder device for crushing scrap cars, wherein the shredders fall in a separation chamber provided at a discharge part of a conveyor for conveying the shredder iron scraps. A motor core separation method in shredder iron scraps, characterized in that an air jet is blown against the iron scraps to separate the motor cores in the shredder iron scraps from the iron components by wind force from the relationship of the air resistance difference. 2. The method for separating a motor core in shredder iron scrap according to claim 1, wherein the air jet blows in the direction of the maximum projected area of each solid of the shredder iron scrap falling from the discharge part of the conveyor. 3. The method for separating a motor core in shredder iron scrap according to claim 1, wherein the air jet blows air in a direction substantially perpendicular to a falling curve of the shredder iron scrap falling from the discharge part of the conveyor.