KR101434539B1 - Sorting apparatus for raw material and the method thereof - Google Patents

Abstract

The present invention relates to a raw material sorting apparatus and a sorting method thereof, and more particularly, to a raw material sorting apparatus and a sorting method therefor. Transferring the raw material to a charger to charge the raw material; And a step of dropping the charged material between electrode plates provided with a rotating sheet which is disposed apart from the charged material and rotates along the periphery of the electrode member to sort the charged raw material into the charged raw material It is possible to effectively select impurities such as ash and sulfur contained in the raw material, for example, coal, by adhering to the surface of the rotating sheet having polarity opposite to each other and sorting them.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a raw material sorting apparatus,

The present invention relates to a raw material sorting apparatus and a sorting method thereof, and more particularly, to a raw material sorting apparatus and a sorting method that can effectively sort impurities such as ash, sulfur, etc. contained in raw materials such as coal.

Generally, coal used in steel mills includes coal for coke production, pulverized coal injection (PCI), and sintering coal.

In the case of coal for coke production, there is a characteristic that when the coal is indirectly heated, it changes into a very stiff liquid state. Such a phase change phenomenon is used to make pulverized coal into lumpy coke. These properties are not all coal has, but only coal of some kind. It is called bituminous coal because it has liquid state like bitumen. Bituminous coal reserves are limited, and they are priced at a high level due to insufficient supply relative to demand.

The coke is charged with iron ore in order through the upper part of the blast furnace, generating heat, melting the iron ore, and discharging it in the form of slag to the bottom of the furnace. The method of supplying heat to the blast furnace is to add coke to the upper part of the blast furnace, and there is a method of putting the shredded coal together with the hot wind to the bottom of the blast furnace. It is very important to know how well the chips are shredded and how much heat they have to burn because they have to burn well in a short time. Since the waste gas generated in the process of generating heat is not dissipated into the atmosphere but is recovered as a gaseous heat source, various kinds of coal can be used.

Sintering coal is used to supply heat to spectroscopy in the process of making sintered ores by applying heat to spectroscopy such as iron ore. In the sintering process, the sintering coal is directly combusted and the waste gas generated during combustion is discharged to the outside through the chimney. Therefore, the sintering anthracite has a high calorific value, and an anthracite having a low nitrogen content for reducing nitrogen oxides (NOx) It is mainly used.

On the other hand, studies for removing ash constituent minerals and sulfur (S) components from coal have been carried out systematically for a long time, but the development of a screening technology with high screening efficiency and economical efficiency still remains to be solved.

In general coal sorting process, wet process is mainly used, such as selection of specific gravity using spiral, jig and heavy liquid, and float sorting using catcher and foaming agent. In the case of the wet treatment process, the process is complicated and the cost for the sorting is increased because the recycling of the used water and the additional process for treating the wastewater and the dehydration and drying process for removing moisture of the selected coal concentrate are required. However, since coal is an inexpensive energy minerals, it is necessary to develop a technology capable of dry processing in order to economically attract coal.

The expected effects of removing ash and sulfur from coal include increased calorific value of coal, stabilization of combustion, increase in thermal efficiency of power plant due to coal fly ash reduction, and improvement of production efficiency for steel making by reducing slag. In addition, there is an advantage that the time required for equipment repair can be shortened and the operating efficiency can be increased due to abrasion and corrosion reduction in the boiler and furnace due to ash and sulfur.

In order to remove coal ash and sulfur dioxide generated during the combustion of coal, it is necessary to install and operate additional processes such as dust collecting facilities and desulfurization facilities. Therefore, techniques for minimizing the ash and sulfur content of coal prior to combustion It can be important. In order to cope with environmental pollution problem that is strengthened both domestically and abroad, it is necessary to develop a technology that can effectively select the ash and sulfur components of coal.

KR 974206 B KR 459988 B US 2011-36758A

The present invention provides a raw material sorting apparatus and a sorting method thereof that can easily remove impurities contained in a raw material.

The present invention provides a raw material sorting apparatus and a sorting method thereof that enable the use of inexpensive low-quality raw materials.

The present invention provides a raw material sorting apparatus and a sorting method thereof capable of suppressing or preventing environmental pollution.

A raw material selecting apparatus according to an embodiment of the present invention is an apparatus for selecting a main component and an impurity constituting a raw material, comprising: a raw material feeder for feeding a raw material; A charger for charging the raw material supplied from the raw material feeder; An electrostatic separator for separating the charged raw material in accordance with the polarity of the charged electricity; And a sorting storage for separating and collecting the raw materials falling down in the electrostatic separator, wherein the electrostatic separator comprises an electrode member spaced apart from the electrode member and a rotating sheet rotating around the electrode member, And a plate.

The raw material feeder includes: a raw material reservoir for storing a raw material; And a gas supplier for moving the raw material discharged from the raw material reservoir to the loader. At this time, a dehumidifier may be provided in front of the gas supply unit.

The charge electricity may include a charge pipe through which the raw material supplied from the raw material supply unit is moved and charged. An uneven structure may be formed inside the lower tube, and a heating device may be provided in the lower tube.

In addition, an auxiliary discharge device may be provided at an end of the discharge pipe to collect the charged material in the discharge device and input the raw material to the electrostatic separator. The auxiliary discharge device may be driven by a cyclone method.

The auxiliary load may be provided with a dust collector for collecting dust and water contained in the charged raw material.

The electrode plate includes a negative electrode plate and a positive electrode plate spaced apart from the negative electrode plate. The negative electrode plate and the positive electrode plate may be inclined such that the lower portion faces outward.

The negative electrode plate and the positive electrode plate may be formed so as to control at least one of the distance and the angle.

The rotating sheet may be formed of at least one of polyethylene (PE), polypropylene (PP), polyvinyl chloride (PVC), polyvinylidene chloride (PVDC), polyimide (PI), and polyethyleneterephthalate (PET).

A scraper may be provided at one side of the electrode plate to separate the raw material adhered to the rotating sheet and a recovering device may be provided to recover the middle ring falling between the electrode plates and supply the middle ring to the raw material feeder.

A raw material selecting method according to an embodiment of the present invention is a device for selecting a main component and an impurity constituting a raw material, comprising the steps of: preparing a raw material; Transferring the raw material to a charger to charge the raw material; And a step of dropping the charged material between electrode plates provided with a rotating sheet which is disposed apart from the charged material and rotates along the periphery of the electrode member to sort the charged raw material into the charged raw material And adhere to the surface of the rotating sheet having polarity opposite to that of the rotating sheet.

The charge for charging the raw material may be heated during the charging of the raw material.

The charge may be heated from room temperature to 200 占 폚.

In the selection process, the scrapers disposed on one side of the rotating sheet may be brought into contact with the rotating sheet to separate the raw materials attached to the rotating sheet and collect them in the sorting reservoir.

Among the charged materials, the middle ring that has not been selected by the electrode plate may be recovered, and a series of processes may be repeatedly selected.

At this time, the raw material is coal, the main component is carbon, and the impurities may be at least one of ash and sulfur.

The raw material sorting apparatus and the sorting method according to the embodiment of the present invention can easily remove impurities contained in a raw material. The purity of the raw material used in the process can be improved by selecting the main component and the impurity using the electrostatic polarity difference of the component contained in the raw material. This makes it possible to use low-cost and low-quality raw materials containing a large amount of impurities, thereby reducing manufacturing costs.

Also, environmental pollution caused by impurities contained in raw materials such as coal, such as ash contents and sulfur, can be suppressed.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing a configuration of a raw material sorting apparatus according to an embodiment of the present invention; FIG.
2 is a schematic view showing a structure of a raw material sorting apparatus according to an embodiment of the present invention.
Fig. 3 is a cross-sectional view schematically showing the internal structure of a feeder of the raw material sorting apparatus. Fig.
4 is a cross-sectional view schematically showing the internal structure of the sorter.
5 is a side view of the sorter.
6 is a view showing a state of use of a raw material sorting apparatus according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It will be apparent to those skilled in the art that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to let you know.

The present invention relates to a sorting apparatus and method for sorting impurities contained in a raw material, and can be used for sorting main components and impurities constituting a raw material by using difference in electrostatic polarity between a main component and an impurity constituting the raw material. Hereinafter, a raw material sorting apparatus for sorting ash and sulfur from coal used in a steel making process and a sorting method thereof will be described as an example.

FIG. 1 is a block diagram showing the construction of a raw material sorting apparatus according to an embodiment of the present invention. FIG. 2 is a schematic view of a raw material sorting apparatus according to an embodiment of the present invention, FIG. 4 is a cross-sectional view schematically showing the internal structure of the sorter, and FIG. 5 is a side view of the sorter.

The raw material sorting apparatus comprises a raw material supplier 100 for supplying a raw material, a charger 200 for charging a raw material supplied from the raw material supplier 100, and a charger 200 for separating the charged raw material from the charger 200 according to the polarity And a screening / storing device 400 for collecting raw materials falling down and sorted by the electrostatic screening device 300 and the electrostatic screening device 300.

The raw material supplier 100 includes a raw material reservoir 110 for storing a raw material such as coal and a gas supplier 120 for moving the raw material discharged from the raw material reservoir 110 to the charger 200.

The raw material storage unit 110 stores the pulverized coal to a predetermined size and a raw material supply pipe 112 for supplying coal to the load unit 200 is provided below the raw material storage unit 110. The raw material supply pipe 112 is provided with a first valve 114 for discharging the coal stored in the raw material storage 110 by a predetermined amount.

The gas supplier 120 supplies a gas, for example, air, for moving the coal extracted from the raw material reservoir 110 to the raw material supply pipe 112 to the charger 200. A gas supply pipe 122 for supplying gas to the raw material supply pipe 112 is connected to the gas supply unit 120 and a second valve 123 for controlling the amount of gas supplied to the gas supply pipe 122 is provided do. The gas supply unit 120 is provided with a dehumidifier 124 for suppressing the decrease in the charge and sorting efficiency of coal by removing water contained in the gas supplied to the material supply pipe 112 through the gas supply pipe 122 . The dehumidifier 124 may be provided in front of the gas supplier 120, for example, between the gas supplier 120 and the second valve 123.

The feeder 200 includes a feed pipe 202 for moving and charging coal supplied from the feeder 100.

The lower pipe 202 has a hollow pipe shape and is disposed in the vertical direction so as to move the coal upward in the lower direction. An uneven structure 203 such as a screw thread may be formed on the inner wall of the lower tube 202. The concavoconvex structure 203 is intended to increase the probability of collision and friction between the coal particles and the inner wall of the lower tube 202, thereby enhancing the charging efficiency of the coal particles. In addition, a charged substance such as copper (Cu) may be formed in the lower tube 202. With this configuration, the coal particles move along the lower pipe 202 and are charged to have a negative charge (+) or a positive charge (+) through the collision between the coal particles and the collision and friction between the coal particles and the charged particles. At this time, the carbon (C) component as the main material among the coal particles is charged to be positively charged, and the sulfur (S) component and ash are charged to be negatively charged. When the particles collide or rub against different particles or charged substances, the principle of charging of the coal particles causes the movement of electrons in the direction in which the Fermi levels of the two materials are equal due to the difference of the work function values, When particles are separated from each other due to collision or friction, an excess or deficiency of electrons occurs and the particles are positively charged (+) or negatively charged (-).

At this time, in order to improve the charging efficiency of the coal particles, a heating device 204 may be provided in the lower pipe 202. The heating device 204 may be formed of an induction heating coil or a surface heating element or the like and may be formed to surround the outer circumferential surface of the lower tube 202 to uniformly heat the lower tube 202. The charging tube 202 may be heated to a temperature of 200 ° C or lower by using the heating device 204 to improve the charging efficiency of coal particles such as carbon, sulfur, ash and so on.

The lower end of the lower end of the feed pipe 202 is connected to the upper end of the lower end of the lower end of the lower end of the feed pipe 202, 300). At this time, the charging rate of the charged coal particles may be lowered at the upper part of the lower end of the charging tube 202 bent toward the electrostatic precipitator 300. The auxiliary charger 204 for improving the charging efficiency of the charged coal particles and controlling the moving direction of the charged coal particles may be provided on the upper portion of the electrostatic separator 300. The sub-electricity generator 204 can be driven in a cyclone manner in which the charged particles are rotated and charged as a whirlpool from the inside. The auxiliary loader 204 may be provided with a dust collecting device 210 for removing moisture contained in the charged coal particles while moving along the lower pipe 202 and for removing fine dust. The moisture supplied from the raw material feeder 100 to the coal feeder 200 is removed by the dehumidifier 124, but the moisture contained in the coal is supplied to the coal feeder 100 It may evaporate in the process of heating the whole tube 202 and may exist in the lower tube 202. If the water content is present in the lower pipe 202, the efficiency of the coal particles is lowered. Therefore, dust is removed from the dust collector 210 and water is removed, and then the charged coal particles are recharged in the sub- The charging efficiency can be further improved.

The auxiliary electricity generator 204 may include a discharge pipe 206 for discharging the charged coal particles to the electrostatic separator 300.

In addition, a buffer plate 302 may be provided under the discharge pipe 206 to buffer the moving speed of the charged coal particles discharged while rotating in the auxiliary loader 204. The buffer plates 302 are spaced apart from each other and are configured to discharge the charged coal particles therebetween to the electrostatic separator 300. The buffer plate 302 may prevent the charged coal particles discharged at a high speed from the auxiliary loader 204 from flowing out to the outside. Further, the buffer plate 302 may be provided with a vibrating device 304. The vibrating device 304 can vibrate the buffer plate 302 to further alleviate the traveling speed of the charged coal particles discharged through the discharge port. In addition, the vibrating device 304 may disperse the charged coal particles discharged to the buffer plate 302 between the buffer plates 302 so as to be uniformly injected into the electrostatic precipitator 300.

The electrostatic screening device (300) includes electrode plates (320a, 320b) and a power supply device (360) spaced apart from each other. The electrostatic screening device 300 may be installed in the chamber 301 to prevent dust from being generated when the charged coal particles are dropped and sorted. The electrode plates 320a and 320b may include a negative electrode plate 320a for separating positively charged carbon particles and a positive electrode plate 320b for separating negatively charged sulfur particles and ash. The cathode plate 320a and the anode plate 320b may include an electrode member 322 formed to have a predetermined area and the electrode member 322 may be formed in a lattice shape. The negative electrode plate 320a and the positive electrode plate 320b may be disposed to face each other and be spaced apart from each other. That is, the negative electrode plate 320a and the positive electrode plate 320b may be inclined so as to have inclined surfaces. The negative electrode plate 320a and the positive electrode plate 320b may be disposed at an angle of about 20 to 60 ° C. The negative electrode plate 320a and the positive electrode plate 320b may be disposed on the upper An angle adjusting device 326 for adjusting the angle of the anode plate 320a and the anode plate 320b may be provided to adjust the angle between the cathode plate 320a and the anode plate 320b within the above range. The electrode member 322 may be connected to the angle adjuster 326 through a connector 325. The negative electrode plate 320a and the positive electrode plate 320b are discharged from the lower electrode 200 (or the auxiliary discharge electrode 204) and are discharged to the outside through the negative electrode plate 320a and the positive electrode plate 320b, The angle can be adjusted according to the amount and sorting efficiency. For example, when the amount of coal particles falling between the cathode plate 320a and the anode plate 320b is large, the angle between the cathode plate 320a and the anode plate 320b can be increased. Alternatively, the angle between the anode plate 320a and the cathode plate 320b may be reduced to increase the sorting efficiency.

A power supply 360 supplies power to each electrode member 322.

A rotating sheet 329 may be provided around the electrode member 322 to rotate along the longitudinal direction of the electrode member 322. A driving device 328 such as a pulley may be provided at the lower portion (or the upper portion) of the electrode member 322 to rotate the rotating sheet 329 outside the electrode member 322. The rotating sheet 329 may be manufactured using a synthetic resin such as PE, polypropylene, polyvinyl chloride, polyvinylidene chloride (PVDC), polyimide (PI), polyethyleneterephthalate (PET) And may be formed to have a thickness enough to transmit an electric field generated in the second electrode 322.

4 and 5, the rotating seat 329 rotates through the driving of the driving device 328 provided at the lower portion thereof. The upper side of the rotating seat 329 is in contact with the angle adjusting device 326, The rotating sheet 329 may be damaged by friction with the angle adjusting device 326. [ Accordingly, the central portion of the angle regulating device 326 to which the electrode member 322 is connected is fixed, and the outer peripheral surface of the electrode member 322 is rotatable so that the rotating sheet 329 can rotate smoothly.

Through such a configuration, the charged coal particles fall into a space between the electrode plates 320a and 320b, that is, between the negative electrode plate 320a and the positive electrode plate 320b, while the carbon particles that are positively charged and the negatively charged sulfur particles and ash And moves toward the electrode plates 320a and 320b having opposite polarities. Each particle is attached to a rotating sheet 329 rotating along the periphery of the electrode member 322 and the particles attached to the rotating sheet 329 are attached to the surface of the rotating sheet 329, 329, respectively.

A scraper 340 may be provided on one side, preferably outside, of the electrode plates 320a and 320b. The scraper 340 is provided to contact the surface of the rotating sheet 329, preferably along the width direction of the rotating sheet 329, to separate the particles attached to the rotating sheet 329 from the rotating sheet 329. At this time, since the electrode plates 320a and 320b are configured to be adjustable in angle, the scraper 340 can be configured to be movable in the left and right directions according to the angle formed by the electrode plates 320a and 320b.

A plurality of sorting reservoirs 410, 420, and 430 are provided under the electrode plates 320a and 320b. One of the selective accumulators 410, 420, and 430 may be provided on the cathode plate 320a side, the anode plate 320b side, and the anode plate 320a and the anode plate 320b. Each of the sorting reservoirs 410, 420 and 430 is arranged side by side and the upper part of the adjacent sorting reservoirs 410, 420 and 430 is provided with coal particles falling from the upper part, such as carbon particles, sulfur particles, A separation plate 350 may be provided. The separator plate 350 is formed to have an inclined surface and the inclination angle of the inclined surface can be adjusted by the angle adjuster 352 so that the coal particles falling from the electrode plates 320a and 320b are separated by the selective accumulators 410, 430).

Particles that are not charged or particles that are not attached to the electrode plates 320a and 320b among the charged particles in the process of moving along the charge 200 fall directly between the electrode plates 320a and 320b. The falling coal particles, such as the middle ring, are introduced into the sorting storage 430 provided between the cathode plate 320a and the anode plate 320b. The middle ring stored in the sorting reservoir 430 may be transferred to the raw material feeder 100 through a separate recovery device 500 such as a conveying pipe, a conveyor belt, or the like. The middle ring transferred to the raw material feeder 100 side may be stored in the intermediate ring reservoir 520 and the intermediate ring reservoir 520 may be connected to the raw material supply pipe 112 by a middle ring supply pipe 522. The middle ring supply pipe 522 may be provided with a third valve 524 for adjusting the discharge amount of the middle ring. The middle ring discharged from the middle ring reservoir 520 flows into the raw material supply pipe 112 through the middle ring supply pipe 522 and is supplied to the load 200 through the gas supplied from the gas supply device 120 Can be moved. In the charger 200, the coal raw material, the middle ring, or the mixture supplied from the raw material supply pipe 112 is charged and charged into the electrostatic separator 300 to select the carbon material as the main material and the ash and the sulfur as the impurities .

Hereinafter, a raw material selection method according to an embodiment of the present invention will be described.

FIG. 6 is a view showing a use state of the material sorting apparatus according to an embodiment of the present invention.

Such as coal, to the raw material supply pipe 112. The gas supply unit 120 supplies gas such as air to the gas supply pipe 122 and supplies the raw material to the raw material supply pipe 112 And transfers the discharged coal to the charger 200. At this time, the moisture supplied to the air supplied from the gas supply unit 120 is removed through the dehumidifier 124 disposed in front of the air supply unit.

The coal moved to the down loader 200 moves up and down along the lower end of the lower pipe 202 to collide with the concave and convex structure 203 of the coal particles, Charged to have a positive charge. Here, carbon particles in coal are charged positively, while sulfur particles and ash are negatively charged. When the coal particles are charged, the charging efficiency can be improved by heating the charging tube 202 to a predetermined temperature of 200 ° C or less by a heating means.

The charged particles moving along the lower tube 202 pass through the auxiliary load 204 at the end of the lower tube 202 to increase the charging efficiency and the fine dust and moisture are removed through the dust collector 210.

The charged particles are injected into the electrostatic separator 300 from the auxiliary load 204 through the buffer plate 302.

The electrode plates 320a and 320b of the electrostatic separator 300 are applied with a voltage of about 10000 to 30000V from the power supply 360 and the negative plate 320a and the positive plate 320b are negatively charged and positively charged, respectively. The particles charged into the electrostatic separator 300 fall down between the electrode plates 320a and 320b while the positively charged carbon particles adhere to the negative electrode plate 320a and the negatively charged sulfur particles and ash are adhered to the positive electrode plate 320b. More preferably, the particles are attached to the surface of the rotating sheet 329, which is provided to rotate around the negative electrode plate 320a and the positive electrode plate 320b. The particles not adhered to the electrode plates 320a and 320b, that is, the negative electrode plate 320a and the positive electrode plate 320b, fall down directly between the electrode plates 320a and 320b. At this time, it is preferable that the rotating sheet 329 rotates in the direction of descending at the central portion of the electrostatic separator 300 in which the charged particles fall, and rising at the outer side. This is to allow the falling particles to adhere to the rotating sheet 329 easily.

The particles attached to the rotating sheet 329 are rotated along the rotating sheet 329 and then contacted with the scraper 340 provided outside the rotating sheet 329 and separated from the rotating sheet 329, 420). Particles falling between the electrode plates 320a and 320b, that is, the middle ring are introduced into the sorting reservoir 430 provided between the electrode plates 320a and 320b, and are collected by the collecting device 500 in the middle ring reservoir 520 .

Although the present invention has been described in connection with certain exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Therefore, the scope of the present invention should not be limited by the described embodiments, but should be defined by the appended claims and equivalents thereof.

100: raw material feeder 200:
202: Lower hall 204: Auxiliary electricity
210: dust collector 300: electrostatic separator
320a, 320b: electrode plate 329:
400: sorting reservoir

Claims (20)

As an apparatus for selecting a main component and an impurity constituting a raw material,
A raw material feeder for feeding the raw material;
A charger for charging the raw material supplied from the raw material feeder;
An electrostatic separator for separating the charged raw material in accordance with the polarity of the charged electricity; And
A sorting device for sorting and collecting raw materials falling down and sorted by the electrostatic sorting machine;
Lt; / RTI >
Wherein the electrostatic separator comprises an electrode member disposed apart from the electrode member, and an electrode plate including a rotating sheet rotating around the electrode member,
And the auxiliary electricity is collected at the end of the discharge pipe and charged into the electrostatic separator by collecting the charged material in the discharge electricity, And a dust collector for collecting dust and moisture contained in the charged raw material is provided in the auxiliary load. The method according to claim 1,
The raw material feeder includes:
A raw material reservoir for storing the raw material;
And a gas feeder for moving the raw material discharged from the raw material storage device to the downstream raw material. The method of claim 2,
And a dehumidifier is provided in front of the gas feeder. delete The method according to claim 1,
And a concavo-convex structure is formed inside the bottom pipe. The method of claim 5,
And a heating device is provided in the lower pipe. delete The method according to claim 1,
Wherein the auxiliary load is driven in a cyclone manner. delete The method according to claim 1,
Wherein the electrode plate includes a negative electrode plate and a positive electrode plate spaced apart from the negative electrode plate, wherein the negative electrode plate and the positive electrode plate are disposed so as to be inclined such that the lower portion faces outward. The method of claim 10,
Wherein the negative electrode plate and the positive electrode plate are formed so as to be capable of adjusting at least one of a distance and an angle. The method of claim 11,
Wherein the rotating sheet is formed of at least one of polyethylene (PE), polypropylene (PP), polyvinyl chloride (PVC), polyvinylidene chloride (PVDC), polyimide (PI), and polyethyleneterephthalate (PET). The method of claim 12,
And a scraper for separating the raw material adhered to the rotating sheet is provided on one side of the electrode plate. The method according to claim 1,
And a recovery device for recovering the middle ring falling between the electrode plates and supplying the recovered middle ring to the raw material supply device. delete delete delete delete delete delete

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