KR101703844B1 - The abandoned magnesia carbon recycling system - Google Patents

Abstract

The present invention relates to a waste magnesia carbon recycling system comprising a sorting unit 110 comprising a collection tank 111, a conveyor 112, a work table 113 and a discharge tank 114, a crusher 121, A drying unit 140 composed of a drying furnace 141 and a heater 143; and a drying unit 140 composed of a drying furnace 141 and a heater 143. The drying unit 140 comprises a water treatment unit 130 comprising a water treatment tank 131 and a treatment water supply unit 132, Since the crushing unit 151 including the crusher 151 and the packing machine 152 is included in the crusher 151, it can be recycled as a raw material of high quality refractory material at the time of disposal of the magnesia crucible used mainly as a furnace material .

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a waste recycling system,

The present invention relates to a waste magnesia carbon recycling system, and more particularly, to a waste magnesia carbon recycling system. More particularly, the present invention relates to a waste magnesia carbon recycling system, To a recycling system for a waste magnesia carbon recycling system.

BACKGROUND ART In general, refractory bricks having high refractivity are used as furnace materials in melting furnaces such as furnaces, smelting furnaces, and refining furnaces, which are used in manufacturing processes of steelmaking and steel making, machinery and casting.

Refractory bricks are required to have high fire resistance, high strength and thermal shock resistance, and strong resistance to chemical erosion due to melts. This is largely different depending on the type of refractory used as a raw material of refractory bricks and the manufacturing process.

Such refractory bricks are classified into quartz, clay, high alumina and magnesia bricks according to the main raw materials of refractories. In recent years, magnesia kaolin, alumina magnesia kaolin, alumina silicon carbide carbonaceous bricks are mainly used.

Magnesium carbide (MgO-C) bricks are made of magnesia and graphite as main materials and used as interior materials for electric converters, electric furnaces and ladles.

Alumina, magnesia, and graphite are mainly used as the main material of the alumina magnesia core (Al ₂ O ₃ -MgO-C) bricks, and they are mainly used for refining ladles.

The alumina silicon carbocarbon (Al ₂ O ₃ -SiC-C) brick is made of alumina, silicon carbide and graphite as main raw materials.

In addition, the raw materials include a binder made of a polymer synthetic resin such as a phenolic resin for enhancing the bonding force and moldability of the particles constituting the refractory, and a metal Al, Si, Mg-Al, It is used in the manufacture of bricks.

In the conventionally known Japanese Patent Laid-open Publication No. 10-2015-7013464, there is disclosed a magnesia carbon brick containing a magnesia raw material and graphite in an amount of 3% by mass or more and 25% by mass or less in terms of the ratio of the sum of the magnesia raw material and graphite, By mass or more and 97% by mass or less, and has an apparent porosity of 7.8% or less after calcination and firing at 1400 ° C for 3 hours.

On the other hand, when a refractory brick is used for a certain period of time, various kinds of slag and foreign matter are fused to the surface of the brick, that is, the surface of the melted metal, which is in contact with the metal.

As a result, refractory bricks that have reached their service life for a certain period of time are discarded and replaced periodically with new refractory bricks in order to exhibit basic fire resistance as a furnace material.

In Korea, thousands of tons of refractory bricks are replaced with new refractory bricks in the year. Refractories, which are the raw materials of new refractory bricks, are currently dependent on imports.

Published Patent No. 10 - 2015 - 7013464 Published Patent No. 10 - 2015 - 7013462 Patent No. 10-0305611 - 0000 Published Patent No. 10 - 2003 - 0038856

In order to overcome the above-mentioned problems, various methods have been proposed for recycling the refractory bricks which have expired in recent years without discarding the refractory bricks as they are, and the most commonly used methods in the industry are pulverizing refractory bricks The refractory bricks are recycled through the method of mixing the refractories with a certain amount of the refractory bricks during the formation of new refractory bricks.

However, when the refractory brick is regenerated by the above-described method, cracks are easily generated in the melting process at an ultra-high temperature when used as a furnace material, so that the molten metal penetrates, defects due to abnormal expansion, Various problems have arisen due to the following reasons. Specifically, the following are as follows.

In the refractory brick, metal Al or metal Si, which prevents the oxidation of graphite (C), is mixed. As described above, reactions such as 4Al + 2Al ₄ C ₃ + 3C and Si + SiC + do.

Therefore, a large amount of Al ₄ C ₃ and SiC are contained in the waste refractory brick, and it is natural that the material is included even if the waste refractory brick is crushed.

However, since the above materials have a characteristic of expanding the volume upon binding with moisture in the atmosphere, recycling the waste refractory bricks as refractory bricks may cause problems such as appearance cracks and breakage or breakage.

In addition, the phenolic resin added as a binder in the manufacture of refractory bricks is present in the form of powder or particles during pulverization in order to recycle the waste refractory bricks. In this state, the adhesion force with the binder added during refractory brick molding is significantly reduced .

As a result, when the phenolic resin powder or particles contained in the waste refractory brick are positioned on the surface of the refractory brick during the regeneration, the powder or the particles flow down without being adhered to the binder to form a groove, Which is another cause of cracking due to inflow and expansion.

The above-mentioned problems are already well known in the related art, and any one of those skilled in the art would appreciate the facts.

As described above, as a method of recycling the waste refractory bricks normally used at present, it is impossible to regenerate the normal refractory bricks and the second problem due to mass production of the defective products is caused. Therefore, It is necessary.

Accordingly, the present invention has been made to solve the above-mentioned problems,

The waste-magnesia carbon recycling system of the present invention,

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A conveyor 112 for conveying the raw material in the direction of the workbench 113 in the collection tank 111 and a conveyor 112 for taking the raw material from one side in the traveling direction of the conveyor 112 A sorting unit 110 comprising a work table 113 for separating slag and foreign matter fused to the surface automatically or manually, and a discharge tank 114 for separately collecting slag and foreign matter separated from the raw material;

A crusher 121 disposed at the back of the conveyor 112 in the traveling direction to crush the raw material to be conveyed and crushing the crushed raw material to a predetermined size, a method of distributing the crushed raw material to the cage- A crushing unit (120) comprising an ejector (122) for ejecting ink;

A water treatment tank 131 in which a container C containing the crushed raw materials is accommodated and a predetermined volume is formed so as to wash the treated water, a treatment water supply unit 132 for supplying water heated to a predetermined temperature to the water treatment tank 131, A water treatment unit 130 comprising:

A drying furnace 141 in which a rail 142 is provided on the floor so that the container C containing the water-treated raw material is transported and loaded into the inner space through the inlet I; A drying unit 140 composed of a heater 143 for heating and cooling water;

A crusher 151 disposed at the outlet O side of the dryer 141 for crushing the dried raw material to a particle size of various preset sizes and discharging the crushed material by the particle size, And a packing machine 152 for collecting the packing material in a packaging bag.

Accordingly, it is possible to achieve the object of recycling the high-quality refractory material after a series of processing steps after collecting it as a raw material at the time of discarding the essential magnesia brick which is mainly used as furnace material.

The present invention relates to a method for recycling a waste refractory brick which has been conventionally used, and has various problems caused by a method of pulverizing a waste refractory brick as it is to be processed into particles and mixing it with a new refractory brick during molding, The present invention is advantageous in that it provides a recycling method capable of manufacturing refractory bricks of high quality by using the essential raw material of waste magnesia car and an optimum recycling system capable of efficiently carrying out the method.

Therefore, waste refractory bricks, in which more than a thousand tons of waste are discarded per year, can be recycled as refractory bricks by collecting the essential materials of magnesia, which can contribute to various economic benefits as well as environmental protection by recycling expensive imported resources And the like can be expected.

1 is a process flow diagram according to an embodiment of a recycling method using the waste magnesia carbon recycling system of the present invention.
2 is a perspective view of an embodiment of a waste recycle system of the present invention.
3 is a plan view of an embodiment of a waste magnesia carbon recycling system of the present invention.
Fig. 4 is a front view of an embodiment of the waste recycle system of the present invention. Fig. 4 (a) is a sectional view taken along line AA in Fig. 3, and Fig. 4 (b) is a front view showing a section taken along line BB.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the construction and operation of the waste recycle system of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a process flow diagram according to an embodiment of a recycling method using the waste magnesia carbon recycling system of the present invention. FIG. 2 is a perspective view of an embodiment of the waste recycle system of the present invention. Fig. 4 is a front view according to an embodiment of the waste recycle system of the present invention, wherein (a) is a section taken along the line AA in Fig. 3, and (b) A cross-sectional front view will be described together.

The waste magnesia carbon recycling system to which the technology of the present invention is applied is used as a furnace material in a furnace, a smelting furnace, etc. in the field of steelmaking and steel industry, and is subjected to a series of processing steps using magnesia- It is noted that the present invention relates to a recycling method and a recycling system for waste magnesia carbon which is recycled as a high-quality raw material free from cracks and the like even when used in the regeneration of refractory bricks.
2 to 4, the waste magnesia carbon recycling system 100 of the present invention includes a screening unit 110, a shredding unit 120, a water treatment unit 130, a drying unit 140, And a crushing unit 150. The concrete configuration of the system 100 according to the process of the series of steps S10 to S50 is as follows.
The sorting unit 110 includes a collection tank 111 containing the waste material of the waste magne- sica carburetor, a conveyor 112 for conveying the raw material in the collection tank 111 in the direction of the work table 113, A workbench 113 for separating the slag and the foreign material fused to the surface automatically or manually by taking the raw material from one side in the traveling direction, and a discharge tank 114 for separately collecting slag and foreign matter separated from the raw material.
The crushing unit 120 includes a crusher 121 disposed at the back of the conveyor 112 in the traveling direction of the conveyor 112 for crushing the crushed raw material to a predetermined particle size and a cage- C to a predetermined amount.
The water treatment unit 130 includes a water treatment tank 131 having a predetermined volume so that the container C containing the crushed raw materials is received and the treated water is desalinated and water supplied to the water treatment tank 131 at a predetermined temperature And a treatment water supply unit 132.
The drying unit 140 includes a drying furnace 141 having a floor 142 on which a container C containing the water-treated raw materials is conveyed to the inside space through the inlet I, And a heater 143 that heats the internal air of the air conditioner.
The crushing unit 150 includes a crusher 151 disposed on the outlet O side of the drier 141 for crushing the dried crushed material to predetermined particle sizes and discharging the crushed material by the particle size, And a packing machine 152 coupled to the discharge port and collecting the finished product in the packing bag according to the size.

As shown in FIG. 1, the method of recycling the waste recycle system of the present invention as described above is as follows. As shown in FIG. 1, A crushing step (S20) of crushing the crushed raw material to a particle size of not more than 100 mm by introducing the selected raw material into a crusher (121), and a crushing step A water treatment step (S30) of distributing a predetermined amount to the container (C) of a possible cage type, transferring the water to the water treatment tank (131), completely immersing the raw material in the treatment water to discharge the impurities and gas contained therein, A drying step (S40) of transferring the dried material (C) to the drying furnace (141) to evaporate moisture and residual gas contained in the raw material, (S50), which is charged into the granulating step (151), and pulverized into granules having various predetermined sizes to collect finished products by granularity.

The raw material sorting step S10 is a step of collecting the discarded magnesia carbon bricks and then removing the molten metal slag welded to the surface and the portion eroded by the chemical action to select only renewable parts.

The crushing step (S20) is a step of crushing the selected raw material by using a crusher. In the subsequent water treatment step (S30), the raw material is crushed to a particle size of 100 mm or less so as to facilitate permeation of the treated water, do.

If the crushed material is crushed to a size larger than the particle size, the process water may not penetrate into the deep part of the raw material in the water treatment step (S30) or the subsequent drying process (S40) can not proceed smoothly. If the crushed material is crushed too small, The raw material may be burned in the drying step (S40). Therefore, it is preferable that the raw material is crushed at the above-mentioned particle size so that the infiltration and drying of the treated water can proceed quickly.

The water treatment step (S30) is a step of dipping the crushed raw material into the treated water to remove impurities contained in the raw material, that is, metal alumina and phenol resin.

The metal alumina is mixed to prevent the oxidation of graphite during the production of refractory bricks as described above. The metal alumina is reacted with Al ₄ C ₃ and SiC in a high temperature environment such as a melting furnace and causes cracks .

The phenolic resin also has a remarkable deterioration in adhesion to a binder added in refractory brick molding in the powdery or granular state, which is another cause of cracking of the refractory brick.

Therefore, in the present invention, impurities such as metal alumina and phenol resin are removed through the water treatment step (S30), thereby eliminating the above-mentioned problems, thereby making it possible to recycle the material as a high-quality raw material.

Therefore, in the water treatment step (S30), the raw material is immersed while maintaining the temperature of the treated water at 90 DEG C to 100 DEG C for 48 hours so that the metal alumina and the phenol resin contained in the raw material are completely removed.

If the temperature of the treated water is out of the above range, the hydration reaction of the raw material is not normally performed and the impurities are not effectively dissolved.

If the immersion time exceeds the above range, the magnesia component may be differentiated and the physical properties may be remarkably weakened. If the immersion time is not within the above range, the CO ₂ and COa gas may not be discharged from the raw material, It is possible to cause cracks due to gas expansion.

In the water treatment step (S30), it is effective to immerse the raw material in the water treatment tank while distributing the raw materials in a predetermined amount to the cage-shaped container (C), to effectively transfer the raw materials and infiltrate the treated water, do.

In the drying step (S40), the water-finished raw material is put in an oven to remove moisture and residual gas over a total of 24 hours.

That is, the temperature of the drying furnace 141 was maintained at 320 DEG C for 16 hours so that the water content of the water-treated raw material was 0.5% or less, and then the primary drying was performed. Remove residual gas.

As described above, the temperature and time range applied to the first to the second drying step (S40) are such that the heat penetrates evenly at a proper speed from the surface to the deep part of the raw material to optimize the drying efficiency and the efficiency of discharging residual gas It is preferable not to deviate from the above range.

The pulverizing step (S50) is a step of pulverizing raw materials to various sizes of particle sizes using a pulverizer, collecting finished products by particle size, and packaging them. This means that if the later completed raw materials are recycled and used for the regeneration of refractory bricks, the pulverized raw materials are supplied in various particle sizes according to the molding method.

The above-described waste magnesia carbon recycling system according to the present invention has an advantage in that it can effectively remove impurities contained in the waste material of the waste magnesia carcass to regenerate high-quality refractory bricks completely free from weak points such as cracking and strength reduction .

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Therefore, it is possible to recycle expensive raw materials of magnesia which is discarded more than a thousand tonnes per year for refractory bricks, thereby contributing to various economic benefits as well as environmental protection by recycling expensive imported resources.

S10: raw material sorting step S20: crushing step
S30: Water treatment process S40: Drying process
S50: Crushing process
100: Waste Magnesia Carbon Recycling System
110: sorting unit 111: picker
112: Conveyor 113: Workbench
114: discharge chamber 120: crushing unit
121: crusher 122: ejector
130: water treatment unit 131: water treatment tank
132: process water feeder 140: drying unit
141: drying furnace 142: rail
143: heater 150: crushing unit
151: crusher 152: packing machine
C: Container

Claims (4)

delete A conveyor 112 for conveying the raw material in the direction of the workbench 113 in the collection tank 111 and a conveyor 112 for taking the raw material from one side in the traveling direction of the conveyor 112 A sorting unit 110 comprising a work table 113 for separating slag and foreign matter fused to the surface automatically or manually, and a discharge tank 114 for separately collecting slag and foreign matter separated from the raw material;
A crusher 121 disposed at the back of the conveyor 112 in the traveling direction to crush the raw material to be conveyed and crushing the crushed raw material to a predetermined size, a method of distributing the crushed raw material to the cage- A crushing unit (120) comprising an ejector (122) for ejecting ink;
A water treatment tank 131 in which a container C containing the crushed raw materials is accommodated and a predetermined volume is formed so as to wash the treated water, a treatment water supply unit 132 for supplying water heated to a predetermined temperature to the water treatment tank 131, A water treatment unit 130 comprising:
A drying furnace 141 in which a rail 142 is provided on the floor so that the container C containing the water-treated raw material is transported and loaded into the inner space through the inlet I; A drying unit 140 composed of a heater 143 for heating and cooling water;
A crusher 151 disposed at the outlet O side of the dryer 141 for crushing the dried raw material to a particle size of various preset sizes and discharging the crushed material by the particle size, And a crushing unit (150) comprising a packing machine (152) for collecting the crushed material in a packing bag. delete delete

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