KR101532337B1 - Apparatus for Cooling a heating subject and Cooling Method using the same - Google Patents

Abstract

The present invention relates to a cooling apparatus arranged on an upper part of a moving path of a heating material comprising: a storage unit installed in a distance away from an upper side of a moving path, and having an inner space wherein cooling water is stored; a plurality of injection nozzles extended in a longitudinal direction and installed in the storage unit whose one end is arranged inside the storage unit and the other end is arranged toward the moving path; and a cooling water supply line connected with one side of the storage unit to supply cooling water to the inner space of the storage unit. A control valve to control an amount of supply of cooling water is equipped in the cooling water supply line, and the control valve is connected with a controller to control operation of the control valve. When the storage unit is filled with the cooling water as close to one end of the injection nozzle, the injection nozzle injects the cooling water. Therefore, a uniform quantity of cooling water with uniform pressure can be supplied, and a quantity of supplied cooling water can be controlled in accordance to a heating material.

Description

TECHNICAL FIELD The present invention relates to a heating material cooling apparatus and a cooling method using the same,

The present invention relates to a heating material cooling apparatus and a cooling method using the same, more particularly, to a heating material cooling apparatus capable of supplying uniform pressure and positive cooling water and controlling the amount of cooling water supplied according to a heating material, ≪ / RTI >

The production process of the steel products is as follows. The steel slab is produced through a continuous casting process through a steelmaking process and a steelmaking process. The produced slab is heated, and is subjected to hot rolling and cold rolling, Product. When high-temperature processing is performed in the process of producing the slab through the continuous casting process, iron and oxygen react on the surface of the slab to form various oxide films, which is called scale.

Such a scale acts as a main cause of forming grooves on the surface of the steel during the rolling process, which may deteriorate the quality of the finally produced steel product. A method of spraying high-pressure water to remove the scale of the steel product surface or projecting a large amount of small-sized beads and breaking the scale membrane of the slab surface by the impact. Alternatively, the scale is removed using a scale removing apparatus shown in Korean Patent Publication No. 10-1224016.

Conventionally, prior to removing the scale, the slab is passed through a cooling device that injects cooling water to promote the separation of the slab and the iron oxide necessary for removing the scale through the cooling water. However, since the amount or pressure of the cooling water to be supplied is not constant, the slab and the iron oxide may be separated locally on the surface of the slab, or even subcooling may occur. Thus, scale removal may not be performed properly in the descale apparatus or may cause upward bending in the rolling process.

In addition, the conventional cooling apparatus sprayed cooling water irrespective of the type and thickness of the slab. Therefore, in the case of stainless steel or a thin heating material, the rolling starting temperature must be high, but the cooling operation may cause the rolling operation to be interrupted by the cooling water, resulting in product failure.

Korean Patent Publication No. 10-1224016

The present invention provides a heating material cooling apparatus capable of supplying uniform pressure and positive cooling water and a cooling method using the same.

The present invention provides a heating material cooling device capable of controlling the amount of cooling water supplied according to a heating material and a cooling method using the same.

The present invention provides a heating material cooling device capable of improving the quality of a heated material and a cooling method using the same.

The present invention relates to a cooling device disposed above a moving path of a heating material to supply cooling water, the cooling device comprising: a storage unit spaced apart from an upper side of the movement path, the storage unit having an internal space for storing the cooling water; A plurality of injection nozzles installed in the storage unit, one end of which is disposed inside the storage unit and the other end is disposed toward the movement path, a cooling water supply unit connected to one side of the storage unit, A cooling water supply line, and the injection nozzle injects the cooling water when the cooling water is filled in proximity to one end of the injection nozzle in the storage unit.

Wherein the injection nozzle includes a body portion extending in the longitudinal direction and forming a movement path of the cooling water therein, the filter portion being disposed on the upper portion of the body portion, the filter portion being connected to a lower portion of the body portion, And a jetting unit which is exposed outside the storage unit to jet the cooling water.

A control valve is provided in the cooling water supply line for controlling the supply amount of the cooling water, and the control valve is connected to a controller for controlling the operation of the control valve.

The jetting unit is protruded to the outside of the storage unit and is narrowed from the upper part to the lower part.

The injection unit is formed in the same plane as the lower surface of the storage unit, and contacts the outside of the storage unit having the injection hole through which the cooling water is injected.

The controller includes a transmission / reception unit for exchanging information about the heated material, a system for managing the work details of the heated material, a determination unit for determining whether the control valve is opened or closed according to information of the transmission / reception unit, And a control unit for opening and closing the control valve according to the control signal.

A method for cooling a heating material, comprising the steps of: receiving information on the heating material from a system for managing the working details of the heating material; supplying cooling water uniformly to the heating material in accordance with information about the heating material And stopping the supply of cooling water to the heating material according to the information about the heating material, and transmitting the state of the heating material after cooling to the system.

In the process of receiving the information about the heated material from the system for managing the work details of the heated material, the information includes at least one of the type and the size information of the heated material.

The cooling water is supplied to the central portion of the upper portion of the storage unit in which the cooling water is stored to uniformly supply the cooling water, and a plurality of injection nozzles are provided in the lower portion, and the cooling water is made close to the upper end of the injection nozzle The injection nozzle injects the cooling water.

Wherein the storage unit is connected to a cooling water supply line provided with a control valve and controls at least one of a method of adjusting a time when the control valve is opened according to the information and a method of intermittently opening and closing the control valve, And controls the amount of cooling water.

The heated material includes a cast produced by a casting process.

The cooling device according to the present invention can inject cooling water at a uniform pressure and amount. Therefore, it is possible to prevent the separation of the local heating material and the iron oxide, thereby facilitating the removal of the scale. Further, it is possible to suppress the supercooling of the surface of the heated material and to prevent the occurrence of defects in the rolling process.

In addition, the cooling device according to the present invention can automatically control the amount of cooling water to be sprayed by receiving information such as the type of steel and size of the heating material. Thus, it is possible to prevent the occurrence of defects due to a sudden drop in temperature of the heated material and the increase in scale layer due to scale fusion.

Therefore, it becomes easier to carry out the scaling operation or the rolling operation for the heated material, and the quality of the produced product can be improved by reducing the defects.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing a scaling process and a rolling process of a heating material according to an embodiment of the present invention; FIG.
Figure 2a shows a cooling device according to an embodiment of the invention;
FIG. 2B is a view showing the operation of the cooling device according to the embodiment of the present invention; FIG.
3 shows a cooling device according to another embodiment of the present invention.
4 is a flowchart illustrating a cooling method 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. To illustrate the invention in detail, the drawings may be exaggerated and the same reference numbers refer to the same elements in the figures.

Although the embodiment of the present invention describes the slabs produced in the steel production process by way of example, the scope of application is not limited thereto and can be used for various heating materials.

A cooling device according to an embodiment of the present invention is a cooling device disposed above a moving path of a heating material to supply cooling water, the cooling device comprising: a storage unit installed on the upper side of the moving path; A nozzle, and a cooling water supply line connected to the storage unit to supply cooling water. At this time, the heating material may be a slab.

FIG. 1 is a schematic view illustrating a descaling process and a rolling process of a heating material according to an embodiment of the present invention. Referring to FIG.

First, to understand the present invention, a descaling process and a rolling process of a heating material, for example, a slab S, will be described as an example. Referring to Fig. 1, a slab S can be conveyed by the conveying roller 10. A heating furnace 100 for heating the slab S and a rolling mill 400 for rolling the slab S may be provided in the feeding path of the slab S, A cooling device 300 and a descaler 200 may be provided between the heating furnace 100 and the rolling mill 400 to remove scales generated in the slab S. [ That is, the scale S can be attached to the surface of the slab S heated in the heating furnace 100 due to high-temperature heat. Since such a scale degrades the quality of the slab (S) product, it needs to be removed. The slab S having passed through the heating furnace 100 can pass through the cooling device 300. [ The cooling device 300 may facilitate the separation of the slab S and the iron oxide by injecting cooling water so that the subsequent descaler 200 can easily perform the scaling operation. The descaler 200 may include a plurality of injectors 210 to inject high-pressure water into the slab S, Thus, the scale produced on the surface of the slab S by high-pressure water can be removed. Then, the slab S from which the scale is removed passes through the rolling mill 400, and a slab product can be produced. However, the method by which the scaler 200 removes the scale is not limited thereto and may vary. At this time, in order to improve the quality of the slab product to be produced, it is necessary to control the cooling water injection amount according to the steel type and thickness of the slab S in the cooling device 300 and supply the cooling water with a uniform amount and pressure.

FIG. 2A is a diagram illustrating a cooling apparatus 300 according to an embodiment of the present invention, and FIG. 2B is a diagram illustrating operation of a cooling apparatus 300 according to an embodiment of the present invention.

Hereinafter, the structure of the cooling device 300 according to the embodiment of the present invention will be described in detail.

2, the cooling device 300 is a cooling device 300 disposed above the movement path of the slab to supply the cooling water W. The cooling device 300 is installed on the upper side of the moving path, A storage unit 310 having an inner space formed therein and extending in the longitudinal direction and installed in the storage unit 310 and having one end disposed inside the storage unit 310 and the other end disposed toward the movement path And a cooling water supply line 330 connected to one side of the storage unit 310 and supplying cooling water W to the internal space of the storage unit 310. [ A control valve 340 provided in the cooling water supply line 330 for controlling the supply amount of the cooling water W and a controller 350 connected to the control valve 340 for controlling the operation of the control valve 340 ). When the cooling water W is filled in the storage unit 310 close to one end of the injection nozzle 320, for example, the upper end, the injection nozzle 320 can spray the cooling water W have.

The storage unit 310 may have an internal space in which the cooling water W can be stored. The storage unit 310 may be formed in a rectangular chamber shape. The cooling water W may be supplied into the storage unit 310 and the cooling water W may be sprayed through the spray nozzle 320 to be described later. Can be cooled by the cooling water (W). However, the shape and structure of the storage unit 310 are not limited to these, and may vary.

The injection nozzle 320 according to the embodiment of the present invention includes a body portion 322 extending in the longitudinal direction and forming a path for moving the cooling water W therein and disposed inside the storage unit 310, And a jetting portion 321 connected to the lower portion of the body portion 322 and exposed to the outside of the storage unit 310 to jet the cooling water W can do.

The body portion 322 may extend in the longitudinal direction to form a path through which the cooling water W moves. That is, the body portion 322 may be formed in a circular tube shape. In addition, the body portion 322 can be opened at the upper portion and the lower portion. The body portion 322 can serve as a soldering iron. That is, the body portion 322 may extend in the longitudinal direction within the storage unit 310 and have a predetermined length L. The cooling water W supplied into the storage unit 310 must be filled at a height L or more of the body part 322 and flow into the upper part of the body part 322 in order to be sprayed through the spray part 321. [ The body part 322 can temporarily store the cooling water W in the storage unit 310 until the cooling water W is filled up to the height L or more of the body part 322. [ Even if the plurality of injection nozzles 320 are provided, since the cooling water W is injected while being filled at a constant speed in the entire region of the storage unit 310, all the injection nozzles 320 can cool the cooling water W to a uniform pressure And the amount can be injected. However, the shape and the structure of the body portion 322 are not limited to this, and may be various.

The filter portion 323 may be provided on the upper portion of the body portion 322. The filter portion 323 is formed in a net shape to prevent foreign matter from flowing into the body portion 322 when the cooling water W flows into the body portion 322. Therefore, it is possible to prevent the passage of the cooling water W in the body portion 322 from being clogged by the foreign substance, thereby blocking the injection nozzle 320 or narrowing the travel passage, and thus the cooling water W is not uniformly distributed with the other injection nozzles 320 It is possible to prevent injection at an unacceptable pressure and amount. Further, the filter portion 323 may be protruded upward. That is, if the filter unit 323 is provided flat on the body part 322, foreign matter may accumulate on the filter unit 323 and the filter unit 323 may be clogged. Accordingly, it is possible to prevent foreign matter from accumulating on the filter portion 323 when the filter portion 323 protrudes upward. However, the shape and structure of the filter portion 323 are not limited to this, and may vary.

The jetting section 321 may be provided below the body section 322. In addition, the jetting section 321 may protrude outside the storage unit 310 and be exposed. The jetting portion 321 may be formed to have a narrower width from the upper portion to the lower portion. Accordingly, the jetting section 321 can jet the cooling water W flowing from the body section 322 downward. Thus, the cooling water W is sprayed on the slab passing underneath, so that the slab can be cooled. However, the shape and structure of the jetting section 321 are not limited to this and may vary. When the injection nozzle 320 injects the cooling water W with a uniform amount and pressure, it is possible to prevent subcooling that locally occurs on the surface of the slab.

The cooling water supply line 330 forms a path through which the cooling water W moves. The cooling water supply line 330 may be connected to one side of the storage unit 310, for example, the upper side and communicate with the inside of the storage unit 310. Accordingly, the cooling water W passing through the cooling water supply line 330 may be supplied to the upper portion of the storage unit 310 and be filled from below. At this time, the cooling water supply line 330 may be provided with a control valve 340 for controlling the supply amount of the cooling water W. For example, a solenoid valve may be used as the control valve 340. Thus, the control valve 340 can be automatically controlled through an electronic signal. However, the structure or shape of the cooling water supply line 330 is not limited to this, and may vary. The type of the control valve 340 to be used is not limited to this, and may vary.

The controller 350 is connected to the control valve 340 so as to control the opening and closing of the control valve 350. The controller 350 includes a transmission / reception unit 351 for exchanging information on a slab with a system (MES: Manufacturing Execution System) (not shown) for managing slab work details, A control unit 353 for opening and closing the control valve 340 according to the determination of the determination unit 352. The control unit 353 may include a control unit 352 for controlling the opening and closing of the control valve 340,

The transmission / reception unit 351 can receive information such as the steel type, size, and thickness of the slab from the system, for example, the specification information of the slab. In addition, the transmitting / receiving unit 351 can transmit information on the slab state to the system after the cooling operation for the slab. The transmission / reception unit 351 can transmit this information to the determination unit 352. [ The determination unit 352 can determine how to perform the cooling operation for the slab through the information transmitted from the transmission / reception unit 351. [ For example, if the slabs are stainless steel, 9% nickel steel, titanium steel, or slab thickness less than 10mm, the amount of cooling water (W) to be supplied may be smaller than that of other steel types or thicknesses. That is, in order to prevent the rolling starting temperature from being lowered and causing defects, it is necessary to control the amount of cooling water (W) supplied in the case of thin slabs to suppress rapid cooling of the slab surface. Accordingly, the determination unit 352 can determine that the amount of the cooling water W to be supplied or the supply of the cooling water W should be stopped when the steel type or thickness of the slab is the same as above. Conversely, if the above-described case is exceeded, the determination unit 352 can determine that the cooling water W should be supplied.

This determination of the determination unit 352 may be transmitted to the control unit 353. [ The control unit 353 can open / close the control valve 340 according to the determination of the determination unit 352. [ If the control valve 340 is a solenoid valve, the control unit 352 may open or close the control valve 340 through an electronic signal to supply or cut off the cooling water W. Meanwhile, the control unit 353 may control the control valve 340 to adjust the amount of the cooling water W injected into the slab. For example, the control unit 353 can control the time that the cooling water W is supplied to the slab by controlling the opening time of the control valve 340 while opening and closing the control valve 340. When the control valve 340 is opened for a short time, the amount of the cooling water W to be sprayed is reduced, and when the control valve 340 is opened for a long time, the amount of the cooling water W to be sprayed can be increased.

Alternatively, the control unit 353 can intermittently send an electronic signal, for example, a pulse to the control valve 340. Then, the control valve 340 is opened and can be supplied with the cooling water W repeatedly while being closed. When the control valve 340 is opened, the coolant W is filled up to the height L or more of the body portion 322 of the injection nozzle 320 and then the control valve 340 is closed so that the height of the body portion 322 (L), the amount of cooling water W to be sprayed can be reduced. However, the criterion for determining whether the control valve 340 is open or closed by the determination unit 352 is not limited to this, and may vary. The method of controlling the injection amount of the cooling water W of the control valve 340 is not limited to this, and may vary.

3 is a view showing an injection nozzle 390 according to another embodiment of the present invention.

Hereinafter, the structure of the injection nozzle 390 according to another embodiment of the present invention will be described in detail. Referring to FIG. 3, the injection nozzle 390 according to another embodiment of the present invention may include a body portion 391 and a jetting portion 392.

The body portion 391 may extend in the longitudinal direction to form a path through which the cooling water W moves. In addition, the upper portion of the body portion 391 may be opened, and the lower portion may be connected to the jetting portion 392, which will be described later. The body portion 391 may extend upward from an inner lower portion of the storage unit 310 to have a predetermined length. The cooling water W supplied into the storage unit 310 must be filled up to the upper portion of the body portion 391 and flow into the upper portion of the body portion 391 in order to be sprayed through the spray portion 392. [ Therefore, even if the plurality of injection nozzles 390 are provided, the cooling water W is injected while being filled at a constant speed in all the regions of the storage unit 310, so that all the injection nozzles 390 can cool the cooling water W to a uniform pressure And the amount can be injected. However, the shape and the structure of the body portion 391 are not limited to this and may vary.

The jetting section 392 may be provided below the body section 391. The jetting section 392 may be formed flush with the lower surface of the storage unit 310 and may contact the outside of the storage unit. Therefore, the manufacturing cost can be reduced compared with the case where the storage unit 310 is protruded to the outside. Further, the jetting section 392 may have a jetting hole whose width is narrower than or equal to the moving path of the cooling water W of the body section 391. Accordingly, the jetting section 392 can jet the cooling water W flowing from the body section 391 downward through the jetting hole. Thus, the cooling water W is sprayed on the slab passing underneath, so that the slab can be cooled. However, the shape and structure of the jetting section 392 are not limited to this and may vary.

4 is a flowchart showing a cooling method according to an embodiment of the present invention.

Hereinafter, a cooling method using a cooling apparatus according to an embodiment of the present invention will be described in detail.

Another cooling method according to an embodiment of the present invention is a method of cooling a heated material, comprising the steps of (S610) receiving information on the heated material from a system for managing the work details of the heated material, (S620) of uniformly supplying cooling water to the heating material (S620), stopping the supply of cooling water to the heating material in accordance with the information about the heating material (S630), and cooling the heating material (S640). At this time, the heating material may be a slab.

When the slab to be cooled is moved toward the cooling device along the movement path, the transmitter and receiver of the controller included in the cooling device can receive the specification information about the slab from the system that manages the slab's operation history. Such specification information may include information such as the steel grade, the size and the thickness of the slab. Thus, it is possible to select how the cooling operation should be performed for the slab through the slab information. The transmission / reception unit can send such information to the determination unit. Then, the judge can check the steel type and thickness of the slab and judge how to proceed with the work.

For example, the judging unit can judge whether the steel type of the slab is stainless steel, 9% nickel steel or titanium steel, and whether the thickness of the slab is less than 10 mm or not. Therefore, if the slab approaching the cooling device deviates from the steel type and has a thickness of 10 mm or more, a control valve opening signal is sent to the control unit, so that the cooling water can be uniformly sprayed to the slab. At this time, in order to uniformly inject the cooling water, the cooling water may be supplied to the central portion of the upper portion of the storage unit where the cooling water is stored, and a plurality of injection nozzles may be provided at the lower portion. Such an injection nozzle can inject cooling water when the cooling water is filled in the storage unit close to the upper end of the injection nozzle.

On the other hand, when the steel grade of the slab is included in the above range or the thickness of the slab is less than 10 mm, the judgment unit can send a shutoff signal to the control unit to lock the control valve. Thus, the supply of cooling water to the slab can be stopped. Therefore, it is possible to prevent a slab with a small thickness from suddenly dropping in temperature to the cooling water and failing to occur.

Alternatively, the judging section can reduce the amount of cooling water supplied to the slab. For example, the control unit can control the time at which the control valve is opened while opening and closing the control valve, thereby adjusting the time at which the cooling water is supplied onto the slab. When the control valve is opened for a short time, the amount of cooling water to be injected is reduced, and when the control valve is opened for a long time, the amount of cooling water to be injected may increase.

Alternatively, the control unit may intermittently send an electronic signal, e.g., a pulse, to the control valve. Then, the control valve can be opened and closed, and the cooling water can be supplied repeatedly. Accordingly, when the control valve is opened, the cooling water is filled to a height equal to or greater than the height of the body of the injection nozzle, and the control valve is closed to reduce the volume of the cooling water repeatedly decreased. Therefore, it becomes easy to remove the scale of the slab in the subsequent work, and it is possible to prevent the slab surface from being undercooled. However, the criterion for determining whether the control valve is opened or closed by the determination unit is not limited to this and may vary. Also, the method of controlling the cooling water injection amount of the control valve is not limited to this and may be various.

The transceiver can send the work progress back to the system after cooling the slab. Accordingly, when proceeding to the process subsequent to the system, it is possible to carry out subsequent work using the information to be transmitted from the transmission / reception unit. Accordingly, the injection efficiency of the cooling water can be controlled automatically according to the thickness of the slab or the type of the slab, so that the efficiency of the operation can be improved and the defective rate of the products produced can be reduced as compared with the case of spraying the same amount of cooling water.

Although the cooling device for supplying the cooling water to the slab has been described above by way of example, the application range of the cooling device is not limited thereto and can be used for various heating materials.

Although the present invention has been described in detail with reference to the specific embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited by the described embodiments, but should be defined by the appended claims, as well as the appended claims.

300: cooling device 310: storage unit
320: injection nozzle 330: cooling water supply line
340: Control valve 350: Controller

Claims (11)

A cooling device arranged above a moving path of a heated material to supply cooling water,
A storage unit spaced above the movement path and having an inner space in which the cooling water is stored;
A plurality of injection nozzles extending in the longitudinal direction and installed in the storage unit, one end of which is disposed inside the storage unit and the other end is disposed toward the movement path;
And a cooling water supply line connected to one side of the storage unit and supplying cooling water to the internal space of the storage unit,
When the cooling water is filled in proximity to one end of the injection nozzle in the storage unit, the injection nozzle injects the cooling water,
Controlling the amount of cooling water supplied to the heating material according to any one of the steel type and size information of the heating material,
Wherein the injection nozzle comprises a body extending in a longitudinal direction and forming a path of movement of the cooling water in the body and disposed in the storage unit, a filter part protruding upward from an upper portion of the body, And a spraying unit connected to the cooling unit and exposed to the outside of the storage unit to spray the cooling water. delete The method according to claim 1,
Wherein the cooling water supply line is provided with a control valve for controlling the supply amount of the cooling water, and the control valve is connected to a controller for controlling the operation of the control valve. The method according to claim 1,
Wherein the jetting portion is protruded to the outside of the storage unit and is narrowed in width from an upper portion to a lower portion. The method according to claim 1,
Wherein the ejection portion is formed in the same plane as the lower surface of the storage unit and is in contact with the outside of the storage unit having the injection hole through which the cooling water is injected. The method of claim 3,
The controller includes a transmission / reception unit for exchanging information about the heated material, a system for managing the work details of the heated material, a determination unit for determining whether the control valve is opened or closed according to information of the transmission / reception unit, And a control unit for opening and closing the control valve according to the control signal. A method for cooling a heated material,
Receiving information on the heated material from a system for managing the work details of the heated material;
A step of uniformly supplying cooling water while preventing foreign matter from flowing into the heating material according to the information about the heating material;
Stopping supply of the cooling water to the heating material according to the information about the heating material; And
And transmitting the post-cooling state of the heated material to the system,
Wherein the information about the heated material includes at least any one of a steel type and size information of the heated material. delete The method of claim 7,
In the process of uniformly supplying the cooling water according to the information about the heated material,
The cooling water is supplied to the central portion of the upper portion of the storage unit in which the cooling water is stored to uniformly supply the cooling water, and a plurality of injection nozzles are provided in the lower portion, and the cooling water is made close to the upper end of the injection nozzle And the injection nozzle injects the cooling water when filled. The method of claim 9,
Wherein the storage unit is connected to a cooling water supply line provided with a control valve and controls at least one of a method of adjusting a time when the control valve is opened according to the information and a method of intermittently opening and closing the control valve, A cooling method for controlling the amount of cooling water. The method according to any one of claims 7, 9, and 10,
Wherein the heating material comprises a cast produced by a casting process.

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