JP5204888B1 - Iron-based material and recycled sand production equipment - Google Patents

Abstract

An object of the present invention is to provide iron or iron oxide particles from stones, rocks, sand, earth, etc., in which iron / iron oxide particles or the like are present, or on which iron / iron oxide layers are adhered. Provides a simple means that can be generated at low cost.
An iron-based material manufacturing apparatus includes a dry rod mill breaker, a magnetic separator, and a sieving device. The rod mill breaker 4 is made by crushing a mineral material containing gravel accompanied with iron or iron oxide, crushed stone particles formed by crushing the gravel, and iron or iron oxide separated from the gravel during crushing of the gravel. To produce particles. The magnetic separator 5 attracts iron or iron oxide particles by magnetic force from a mineral material containing crushed stone particles and iron or iron oxide particles, thereby converting the mineral material into crushed stone particles and iron or iron oxide. Separated into particles of objects. The sieving device 7 classifies the recycled sand from the crushed stone particles.
[Selection] Figure 1

Description

The present invention relates to iron or iron oxide from a mineral material containing gravel, in which iron or iron oxide particles or lumps are present, or on which iron or iron oxide particles or layers are attached . particles and Ru der relates apparatus for producing an iron-based material and the reclaimed sand to produce a reclaimed sand.

  In recent years, the international price of iron ore has soared due to the sharp increase in imports of iron ore in China, so the price of iron-based materials has been on an upward trend in Japan, which depends on imports for almost 100% of iron ore demand. is there. For this reason, not only steel materials used as materials for various iron products, but also iron powder used for heavy metal treatment of wastewater by the iron powder method has been rising.

  On the other hand, generally, stones, rocks, sand, soil, and the like have iron or iron oxide particles or small lumps in the interior, or iron or iron oxide particles or layers are attached to the surface thereof. In addition, iron sand is mixed in the aggregate of sand, soil and the like. In addition, it is estimated that such iron or iron oxide contained in stones, rocks, sand, soil, etc. (hereinafter collectively referred to as “debris”) is 2 to 3% by mass. Therefore, it can be considered that iron is produced from earth and stones that are almost inexhaustible in the country. However, since the iron content of earth and stone is very low compared to the iron content of iron ore (generally 40-60 mass%), it is not possible to produce iron from earth and stone by ordinary iron making techniques such as the blast furnace method. Virtually impossible.

  On the other hand, for example, Patent Document 1 discloses a method for treating a ballast material in which iron (iron oxide) adhering to the surface of the ballast material taken out from the roadbed is separated. Specifically, according to this ballast material processing method, after the ballast material is subjected to grinding treatment under water to produce a slurry, the slurry is divided into a first and a second vibrating sieve, a feed sump, Using a hydrocyclone, an aqua screen, a thickener tank, and a dehydrator, the regenerated ballast material or regenerated aggregate is separated into iron separated from the ballast material.

JP 2002-167702 A

  However, the method for treating a ballast material disclosed in Patent Document 1 separates or removes the iron component adhering to the surface of the ballast material as a harmful component to the recycled ballast or recycled aggregate. It is not intended to be used as an iron-based material or an iron-making material. Further, in this ballast material treatment method, the treatment object is only the ballast material taken out from the road bed, and is not suitable for use with ordinary debris (stone, rock, sand, soil, etc.). Furthermore, this ballast material processing method is a complex processing facility comprising first and second vibrating screens, feed sumps, hydrocyclones, aqua screens, thickener tanks and dehydrators to separate iron from the ballast material. Need. Therefore, the ballast material treatment method disclosed in Patent Document 1 cannot efficiently produce iron or iron oxide from ordinary earth and stones.

  The present invention has been made in order to solve the above-described conventional problems, and iron or iron oxide particles or small lumps exist in the interior, or iron or iron oxide particles or layers on the surface thereof. It is an object to be solved to provide a simple means capable of producing iron or iron oxide particles at low cost from stone, rock, sand, soil, or the like to which iron adheres. In addition, the present invention should solve the problem by providing a simple means capable of generating reclaimed sand and iron or iron oxide particles at low cost from such stone, rock, sand, soil and the like. Let it be an issue.

An apparatus for producing iron-based material and recycled sand according to the present invention, which has been made to solve the above problems, includes a dry rod mill breaker, a magnetic separator, and a sieving device. The rod mill breaker crushes the mineral material containing gravel, in which iron or iron oxide particles or lumps are present, or iron or iron oxide particles or layers are attached to the surface. The crushed stone particles having a particle size of 2 to 1/16 mm formed by crushing the gravel and iron or iron oxide particles separated from the gravel when the gravel is crushed are generated. The magnetic separation device attracts iron or iron oxide particles by magnetic force from a mineral material containing crushed stone particles and iron or iron oxide particles, thereby separating the mineral material into crushed stone particles and iron or iron oxide. Separated into particles. The sieving device classifies the mineral material containing crushed stone particles discharged from the magnetic separator, and extracts reclaimed sand having a desired particle size. The mineral material may contain sand and iron sand.
Here, the magnetic force sorting device includes a drum-shaped rotor that rotates around a rotation shaft that extends in the horizontal direction, and a central angle from the top of the rotor 10 to 20 degrees from the bottom of the rotor as viewed in the rotor rotation direction. In the magnetized region up to a position of 10 to 20 ° in front of the central angle, in the hollow portion of the rotor, a plurality of magnets opposed to the inner peripheral surface of the rotor and arranged adjacent to each other in the rotor circumferential direction, and below the magnetized region A first discharge unit that is disposed and discharges crushed stone particles, a second discharge unit that is disposed below a region other than the magnetized region and discharges particles of iron or iron oxide, and is attached to the rotor in a region other than the magnetized region And a scraper that scrapes off particles of iron or iron oxide adhering to the outer peripheral surface of the rotor. In the magnetized region, a mixture of crushed stone particles and iron or iron oxide particles is dropped by gravity and supplied to the upper surface of the rotor, and the crushed stone particles fall to the first discharge portion by gravity, while iron or iron oxide Particles fall to the second discharge part due to gravity.

The iron-based material and reclaimed sand manufacturing apparatus according to the present invention reduces the iron oxide particles separated by the magnetic separator in a non-molten or semi-molten state by mixing and heating with carbon powder. You may provide the reducing apparatus which produces | generates the particle | grains or lump of iron.

According to the iron-based material and the apparatus for producing reclaimed sand according to the present invention, it is a simple facility consisting of a substantially dry-type rod mill breaker, a magnetic separator and a sieving device, in which iron or iron oxide is contained. Production of iron or iron oxide particles and reclaimed sand at low cost from mineral materials containing gravel with particles or small lumps or iron or iron oxide particles or layers on the surface. be able to.

  Since the iron or iron oxide particles thus produced are in the form of particles or powder, for example, heavy metals or heavy metal compounds or ions thereof in wastewater by the iron powder method (hereinafter referred to as “heavy metals etc.”) As an “iron powder” which is an essential material for the removal of “)”. Here, “iron powder” means iron or iron oxide particles or powder capable of adsorbing or removing heavy metals and the like. In the case where the mineral material includes iron sand, the iron sand is separated from the crushed stone particles by a magnetic separator or a magnetic separator, and is mixed in iron particles or iron oxide particles.

In the iron-based material and the apparatus for producing reclaimed sand according to the present invention, the gravel is crushed into crushed stone particles having a particle diameter of 2 to 1/16 mm, so that the crushed stone particles can be used or sold as reclaimed sand. Alternatively, iron oxide particles can be used or sold as the iron-based material. Therefore, the production cost of reclaimed sand and iron-based material can be reduced as compared with the case of simply producing reclaimed sand from a mineral material or simply producing particles of iron or iron oxide from a mineral material. . Also, since the gravel is crushed using a rod mill breaker, the particle size of the reclaimed sand (crushed stone particles) can be made uniform, and the particle shape of the reclaimed sand can be made uniform, increasing the product value of the reclaimed sand. it can.

In the iron-based material and reclaimed sand manufacturing apparatus according to the present invention, iron oxide particles are mixed with carbon powder and heated to reduce in a non-molten or semi-molten state to produce iron particles or lumps. In the case (direct iron making method), iron oxide particles with a simple structure or process without using a complicated steel making apparatus (indirect iron making method) such as a blast furnace or converter that takes out iron in a molten state. Therefore, a high-quality iron-based material with a low carbon content can be generated.

It is a schematic diagram which shows the structure of the manufacturing apparatus of the reproduction | regeneration sand and iron-type material which concern on this invention. FIG. 2 is a schematic elevation view of a magnetic sorting device that constitutes the manufacturing apparatus shown in FIG. 1.

  Hereinafter, an embodiment of the present invention will be specifically described with reference to FIG. As shown in FIG. 1, the recycled sand and iron-based material manufacturing apparatus 1 according to the present invention (hereinafter simply referred to as “manufacturing apparatus 1”) includes a hopper 2, a first conveyor 3, a rod mill breaker 4, A magnetic separator 5, a second conveyor 6, a sieving device 7, and a third conveyor 8 are provided. In this production apparatus 1, iron or iron oxide particles or small lumps (small pieces) are present in the interior thereof, and / or gravel with iron or iron oxide particles or layers adhering to the surface thereof. The contained mineral material is put into the hopper 2 and stored. The mineral material is transported from the production site to the hopper 2 using, for example, a dump truck.

Here, the “mineral material including gravel” may be composed only of gravel, or may include sand, earth, iron sand and the like in addition to gravel. In addition, in this specification, gravel means mineral objects, such as a stone, a rock fragment, and a concrete piece with a particle size larger than sand (particle size 2-1/16 mm). Soil also refers to a composite of mineral objects that are generally smaller in particle size than sand. In general, gravel contains about 2-3% by mass of iron and / or iron oxide (mainly ferric oxide (Fe ₂ O ₃ ), triiron tetroxide (Fe ₃ O ₄ ), etc.). . In general, an aggregate of sand or earth contains about 0.5 to 3% by mass of iron sand mainly composed of triiron tetroxide (Fe ₃ O ₄ ).

  The mineral material stored in the hopper 2 is supplied by the first conveyor 3 to the dry rod mill breaker 4 (crushing device) at a constant supply speed. The first conveyor 3 may be any material as long as it can transport a mineral material containing gravel continuously or intermittently. For example, a bucket conveyor or a belt conveyor can be used. .

  Although not shown in detail, the rod mill breaker 4 is a crushing device in which a plurality of steel rods (for example, 10 75 mmφ × 2 m steel rods) are arranged in a drum as a crushing tool. The rods roll in parallel with each other and come into line contact, and the impact causes the gravel existing between the rods to be finely crushed to produce crushed stone particles. The rod mill breaker 4 can adjust the particle size of the crushed stone particles and the recycled sand described later, for example, in the range of 2 to 1/16 mm. In addition, adjustment of a particle size can be easily performed by adjusting suitably the kind of steel rod, the arrangement position of a steel rod, the rotation speed of a steel rod, etc., for example.

  And when the gravel is crushed by the rod mill breaker 4, the particles or layers of iron or iron oxide existing in the gravel, or the particles or layers of iron or iron oxide adhering to the surface of the gravel Most of them leave the gravel and become iron or iron oxide particles. Here, most of the iron or iron oxide particles have a particle size in the range of 0.1 to 1 mm. Accordingly, the mineral material discharged from the rod mill breaker 4 includes crushed stone particles and iron or iron oxide particles. In addition, when the mineral material thrown into the hopper 2 contains granular materials other than gravel, for example, sand, earth, sand iron, etc., the mineral material discharged from the rod mill breaker 4 also includes these granular materials. It is. And the granular mineral material discharged | emitted from the rod mill breaker 4 is supplied to the magnetic separator 5 by gravity.

  As shown in FIG. 2, a thin drum-like rotor 11 that rotates at a constant rotational speed in the direction indicated by the arrow A during operation is disposed in the housing 10 of the magnetic force sorting device 5. In the hollow portion of the rotor 11, a plurality of fixed magnets 12 are arranged in the rotor circumferential direction in the region R <b> 1 in the rotor circumferential direction in the vicinity of the rotor inner circumferential surface. The magnets 12 are arranged adjacent to each other in the circumferential direction of the rotor such that the magnetic pole surface of S pole or N pole faces the inner circumferential surface of the rotor. The magnet 12 may be a permanent magnet or an electromagnet. The material of the rotor 11 is not particularly limited as long as it is not a material that is permanently magnetized when a magnetic field is applied.

  Thus, at the time of operation, the rotor 11 rotates in the direction of arrow A while bringing the inner peripheral surface thereof close to or in sliding contact with the magnetic pole surface of the magnet 12 in the region R1. The region R1 is a region that is slightly wider than the right half of the rotor 11 in the positional relationship shown in FIG. Specifically, for example, with respect to the circumferential direction of the rotor, from a position where the central angle is 10-20 ° counterclockwise from the top of the rotor, the central angle is 10-20 ° clockwise from the bottom of the rotor. A plurality of magnets 12 are arranged adjacent to each other over the recessed position.

  On the other hand, the magnet 12 is not disposed in a region other than the region R1 in the rotor circumferential direction, that is, the region R2. The rotor 11 has a predetermined position in the region R2, for example, a central position of the region R2 with respect to the circumferential direction of the rotor, or a position that is turned 20 to 30 degrees counterclockwise or clockwise from the central position at a central angle. A scraper 13 for scraping off particles of iron or iron oxide adhering to the outer peripheral surface of the rotor is attached at a position between the center position. Further, a lower portion of the housing 10 is provided with a first discharge portion 14 for discharging crushed stone particles and a second discharge portion 15 for discharging particles of iron or iron oxide.

  Thus, when the granular mineral material discharged from the rod mill breaker 4 is supplied to the magnetic separator 5, the mineral material falls on the upper surface of the rotor 11 in the region R1. At this time, iron or iron oxide particles are adsorbed on the outer peripheral surface of the rotor by the magnetic force of the magnet 12. In addition, when sand iron is contained in the mineral material, this sand iron is also adsorbed on the outer peripheral surface of the rotor 11. Thus, the iron or iron oxide particles adsorbed on the rotor outer peripheral surface move from the rotor outer peripheral surface by gravity when moving to the region R2 where the magnet 12 does not exist as the rotor 11 rotates in the direction of arrow A. It separates and falls naturally and is discharged from the second discharge part 15. Note that the iron or iron oxide particles remaining on the outer peripheral surface of the rotor without being naturally dropped are scraped off by the scraper 13 and are naturally dropped by gravity and discharged from the second discharge portion 15.

  On the other hand, a granular material other than iron or iron oxide particles in the mineral material, that is, a mixture of crushed stone particles or crushed stone particles, sand, soil, etc. (hereinafter referred to as “crushed stone particles”) is a non-magnetic material. Instead of being attracted to the outer peripheral surface of the rotor 11, it naturally falls by gravity and is discharged from the first discharge portion 14. That is, in the magnetic separator 5, the mineral material is separated into crushed stone particles or the like and iron or iron oxide particles.

  As shown in FIG. 1 again, the crushed stone particles and the like discharged from the magnetic separator 5 are carried into the sieving device 7 by the second conveyor 6. As long as the 2nd conveyor 6 can convey a granular crushed stone particle | grain etc., what kind of thing may be sufficient, for example, a screw feeder, a bucket conveyor, a belt conveyor etc. can be used. The sieving device 7 is provided with a plurality of screens having different sizes or different sizes, and the crushed stone particles and the like have a particle size larger (coarse) than the regenerated sand in a preset particle size range and the regenerated sand. Sieve into coarse particles and fine particles with smaller (fine) particle size than reclaimed sand. That is, the crushed stone particles and the like are classified, and the regenerated sand whose particle size is adjusted is selected and extracted from the crushed stone particles and the like.

  Coarse particles separated by the sieving device 7, that is, mineral particles having a particle size larger than the regenerated sand, are returned to the rod mill breaker 4 by the third conveyor 8 and crushed again. As the 3rd conveyor 8, a screw feeder, a bucket conveyor, a belt conveyor etc. can be used, for example. The coarse particles may not be returned to the rod mill breaker 4 but may be used as an aggregate of construction materials (such as ready-mixed concrete). Further, the fine particles separated by the sieving device 7, that is, mineral particles or powder having a particle size smaller than that of recycled sand, are used as construction materials or landfill materials, or are discarded.

  Although not shown in detail, the regenerated sand whose particle size has been adjusted is discharged from the sieving device 7 and then washed with water using a washing device, so that fine dust mixed in or adhering to the reclaimed sand, etc. Is removed. This recycled sand can be widely used in the same way as natural sand, such as sand for ready-mixed concrete, sand for secondary concrete products, sand for compound plants, sand for pipes, sand for sandboxes, etc. Or it can sell as goods (sand products). Conventionally, natural sand such as river sand, sea sand, mountain sand, etc. has been widely used in the field of civil engineering and construction, but since the collection of natural sand has been regulated in recent years from the viewpoint of environmental conservation, such reclaimed sand is The demand is expected to increase rapidly as an alternative to natural sand.

  In this manufacturing apparatus 1, the sieving device 7 is configured to screen crushed stone particles and the like into one type of recycled sand, coarse particles, and fine particles. However, a larger number of screens may be provided to select and extract a plurality of types (for example, two types, three types, ...) of regenerated sand having different particle size distributions or particle size configurations. In this embodiment, dust is removed by washing the reclaimed sand with water using a washing device. However, dust may be removed by air blow or the like without using water. If there is no particular problem with the quality of the recycled sand, the removal of dust may be omitted.

  On the other hand, the iron or iron oxide particles discharged from the magnetic separator 5 are washed with water using a cleaning device to remove fine dust or the like mixed or adhering to the iron or iron oxide particles. Is done. Note that dust may be removed by air blow or the like without performing such cleaning, and removal of dust may be omitted if not particularly necessary.

  The iron or iron oxide particles produced by the production apparatus 1 can be used as they are for removing heavy metals and the like (heavy metal, heavy metal compounds or ions thereof) in wastewater by the iron powder method. According to the experiments by the inventors of the present application, the iron particles and iron oxide (mainly ferric oxide, ferric tetroxide) particles produced in this way are both capable of adsorbing heavy metals and the like. It was confirmed to have Therefore, when using the iron or iron oxide particles generated in the manufacturing apparatus 1 for removing heavy metals or the like in wastewater by the iron powder method, it is distinguished whether the particles are iron or iron oxide. It is not necessary and can be used as “iron powder” as it is.

  However, according to the experiments of the present inventors, when iron or iron oxide particles are generated from mineral materials collected from the ground or soil (heavy metal-contaminated soil) containing heavy metals, the iron or iron oxide It was proved that the adsorption capacity of heavy particles and the like of these particles was considerably low. The cause is presumed to be that iron or iron oxide particles existing in the ground or soil have already adsorbed heavy metals or the like to their saturated state.

  When the iron or iron oxide particles generated by the production apparatus 1 are not used for removing heavy metals or the like in wastewater by the iron powder method, these iron or iron oxide particles can be used as an iron-making raw material. it can. Therefore, the particles of iron or iron oxide can be sold to a waste product collector or a steel manufacturer, for example, in the same manner as scrap iron.

  Moreover, you may iron- manufacture independently using the particle | grains of the iron oxide produced | generated by the manufacturing apparatus 1. FIG. In addition, since it is virtually impossible that the iron oxide particles are not generated by the manufacturing apparatus 1, only the iron oxide particles are generated by the manufacturing apparatus 1, It is a mixture of iron particles and iron oxide particles. For such a mixture, iron is produced in a state where iron particles and iron oxide particles are mixed.

  When iron-making using such iron oxide particles, the amount of processing is relatively small, so the indirect iron-making method (molten pig iron method) adopted by general steel manufacturers, that is, blast furnaces and converters It is extremely difficult to use an iron-making technique in which iron-making raw materials (iron ore) are reduced while melting at a relatively high temperature (for example, about 1500 ° C.) to produce iron. Therefore, without melting the iron-making raw material, the iron-making raw material and the carbon powder are mixed and heated at a relatively low temperature (for example, 500 to 1000 ° C.), and reduced in a non-molten state or a semi-molten state to form a sponge or lump. It is practical to carry out iron making by a direct iron production method for producing the iron (bulk wrought iron), for example, the Tatara iron production method. In addition, since the iron produced | generated in this way has a low carbon-containing material and is good quality, it can be used as a raw material of a knife (a knife, a sword, etc.), for example. In addition, since the direct iron making method or the iron making method itself is well known to those skilled in the art, the description thereof is omitted.

  As described above, according to the embodiment of the present invention, from a mineral material containing gravel accompanied with iron or iron oxide, the regenerated sand having a relatively uniform particle size and uniform shape, and particles of iron or iron oxide are obtained. It can be manufactured at low cost.

  As described above, the iron-based material production apparatus or method according to the present invention is particularly useful in the field of civil engineering and construction, and is suitable for producing reclaimed sand and / or iron or iron oxide particles.

  DESCRIPTION OF SYMBOLS 1 Manufacturing apparatus, 2 hopper, 3 1st conveyor, 4 Rod mill breaker, 5 Magnetic sorting apparatus, 6 2nd conveyor, 7 Sieving apparatus, 8 3rd conveyor, 10 Housing, 11 Rotor, 12 Magnet, 13 Scraper, 14 1st 1 discharge part, 15 2nd discharge part.

Claims (3)

Mineral material containing gravel containing iron or iron oxide particles or small lumps or iron or iron oxide particles or layers on its surface is crushed, and the gravel is crushed. A dry rod mill breaker that generates crushed stone particles having a particle diameter of 2 to 1/16 mm formed and iron or iron oxide particles separated from the gravel when the gravel is crushed,
By attracting the iron or iron oxide particles by magnetic force from the mineral material containing the crushed stone particles and the iron or iron oxide particles, the mineral material is converted into the crushed stone particles and the iron or iron. A magnetic separator for separating oxide particles;
An iron-based material and a device for producing reclaimed sand, comprising a sieving device for classifying the mineral material containing the crushed stone particles discharged from the magnetic separator and extracting reclaimed sand having a desired particle size,
The magnetic separator is
A drum-like rotor that rotates about a rotating shaft extending in a horizontal direction;
In the magnetized region from the position 10 to 20 degrees behind the central angle from the top of the rotor to the position 10 to 20 degrees front from the bottom of the rotor as viewed in the rotor rotation direction, in the hollow part of the rotor, A plurality of magnets facing the rotor inner circumferential surface and arranged adjacent to each other in the rotor circumferential direction;
A first discharge unit disposed below the magnetized region to discharge the crushed stone particles; a second discharge unit disposed below a region other than the magnetized region to discharge the iron or iron oxide particles;
A scraper attached to the rotor in a region other than the magnetized region, and scraping off the iron or iron oxide particles adhering to the outer peripheral surface of the rotor;
In the magnetized region, a mixture of the crushed particles and the iron or iron oxide particles is supplied by gravity to the upper surface of the rotor, and the crushed particles are dropped to the first discharge portion by gravity. An iron-based material and recycled sand manufacturing apparatus, wherein the iron or iron oxide particles fall onto the second discharge part by gravity.   The iron oxide particles separated by the magnetic separator are mixed with carbon powder and heated to reduce in an unmolten or semi-molten state to produce iron particles or lumps. The iron-based material and recycled sand manufacturing apparatus according to claim 1, wherein   The said mineral material contains sand and sand iron, The manufacturing apparatus of the iron-type material and recycled sand of Claim 1 or 2 characterized by the above-mentioned.

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