KR101178535B1 - Cooling whell unit, method for manufacturing cooling whell unit, and apparatus for manufacturing amorphous fiber - Google Patents

Abstract

The cooling wheel unit for cooling the melt is coated on a cooling wheel that rotates itself and a rotating outer surface of the cooling wheel by using a low temperature spray method, and includes a coating layer in contact with the melt.

Description

COOLING WHELL UNIT, METHOD FOR MANUFACTURING COOLING WHELL UNIT, AND APPARATUS FOR MANUFACTURING AMORPHOUS FIBER}

The present invention relates to a cooling wheel unit, and more particularly, to a cooling wheel unit for cooling a melt, a manufacturing method of a cooling wheel unit, and an amorphous fiber manufacturing apparatus.

The cooling wheel unit includes a self-rotating cooling wheel to contact the cooling wheel with the melt to cool the melt.

However, the rotating outer surface of the cooling wheel unit has a problem in that it is easily contaminated or worn by contact with the hot melt and the material cooled from the melt.

One embodiment of the present invention is to solve the above-described problems, to provide a cooling wheel unit, a manufacturing method of a cooling wheel unit and an amorphous fiber manufacturing apparatus is reduced maintenance time and maintenance cost.

A first aspect of the present invention for achieving the above-described technical problem is a cooling wheel unit for cooling the melt, the self-rotating cooling wheel, and the outer surface of the cooling wheel is coated using a low temperature spray method, It provides a cooling wheel unit comprising a coating layer in contact with the melt.

The cooling wheel may include a support, a shaft rotatably supported by the support, a wheel supported by the shaft, and a cooling passage formed inside the wheel adjacent to an outer surface of the wheel.

The outer surface of the cooling wheel may include a metal, and the coating layer may include an alloy of the metal.

In addition, the second aspect of the present invention is a method for manufacturing a cooling wheel unit for cooling the melt, the self-rotating the cooling wheel, and a coating layer in which the melt is in contact with the rotating outer surface of the cooling wheel using a low temperature spray method It provides a method of manufacturing a cooling wheel unit comprising the step of coating.

In addition, a third aspect of the present invention is a crucible forming a melting space in which the melt is located, a furnace tube communicating with the melting space, forming a flow path through which the melt passes, communicating with the flow path, and ejecting the melt to the outside. It provides a nozzle and an amorphous fiber manufacturing apparatus comprising the cooling wheel unit.

According to one of the embodiments of the above-described problem solving means of the present invention, there is provided a cooling wheel unit, a manufacturing method of a cooling wheel unit, and an amorphous fiber manufacturing apparatus with reduced maintenance time and maintenance cost.

1 is a view showing an amorphous fiber manufacturing apparatus according to a first embodiment of the present invention.
FIG. 2 is a view illustrating the cooling wheel unit shown in FIG. 1.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

In addition, since the sizes and thicknesses of the respective components shown in the drawings are arbitrarily shown for convenience of explanation, the present invention is not necessarily limited to those shown in the drawings.

In the drawings, the thickness is enlarged to clearly represent the layers and regions. In the drawings, for the convenience of explanation, the thicknesses of some layers and regions are exaggerated. It will be understood that when a layer, film, region, plate, or the like is referred to as being "on" another portion, it includes not only the other portion "directly on" but also the other portion in between.

Also, throughout the specification, when an element is referred to as "including" an element, it is understood that the element may include other elements as well, without departing from the other elements unless specifically stated otherwise. Also, throughout the specification, the term "on " means to be located above or below a target portion, and does not necessarily mean that the target portion is located on the image side with respect to the gravitational direction.

Hereinafter, an amorphous fiber manufacturing apparatus according to a first embodiment of the present invention will be described with reference to FIGS. 1 and 2.

1 is a view showing an amorphous fiber manufacturing apparatus according to a first embodiment of the present invention.

As shown in FIG. 1, in the amorphous fiber manufacturing apparatus according to the first embodiment of the present invention, a raw material is formed of a melt M to prepare an amorphous fiber, and a crucible 100, a furnace tube 200, and a stopper 300 are provided. ), The nozzle 400 and the cooling wheel unit 500.

The crucible 100 forms a melting space MS, and forms a fuel M to be handled as a melt M and is positioned in the melting space MS.

The furnace pipe 200 is connected to the crucible 100 and forms a flow path FC communicating with the melting space MS. The melt M located in the melting space MS may move in the direction of the nozzle 400 through the flow path FC of the furnace pipe 200. The furnace tube 200 may include a heat resistant ceramic material such as graphite.

The stopper 300 is located in the melting space MS of the crucible 100, and moves up and down to control communication between the flow path FC of the furnace pipe 200 and the melting space MS of the crucible 100. In detail, when the melt M located in the melting space MS of the crucible 100 passes through the flow path FC of the furnace pipe 200, the stopper 300 is moved upward to move the melt space MS and the flow path. And the melter M flows from the melt space MS to the flow path FC when the stopper 300 is moved downward to block the gap between the melt space MS and the flow path FC. It is blocked from moving.

The nozzle 400 communicates with the flow path FC of the furnace pipe 200, and blows the melt M that has passed through the flow path FC to the outside to bring the melt M into contact with the cooling wheel unit 500.

FIG. 2 is a view illustrating the cooling wheel unit shown in FIG. 1.

As shown in FIG. 2, the cooling wheel unit 500 cools the melt M ejected from the nozzle 400 and includes a cooling wheel 510 and a coating layer 520.

The cooling wheel 510 rotates by itself and includes a support 511, a shaft 512, a wheel 513, and a cooling passage 514.

The support 511 rotatably supports the shaft 512. In detail, one or more bearings may be located at a portion where the shaft 512 is supported, which guides the shaft 512 supported by the support 511 to rotate.

The shaft 512 is rotatably supported by the support part 511 and supports the wheel 513. The shaft 512 rotates itself by a bearing located at the support 511.

The wheel 513 is supported by the shaft 512 and has a circular shape. The outer surface 513a of the wheel 513 includes a metal such as copper (Cu). The cooling passage 514 is positioned inside the outer surface 513a of the wheel 513 and the adjacent wheel 513. The outer surface 513a of the wheel 513 may be formed in a concave-convex shape for coupling with the coating layer 520.

The cooling passage 514 is formed inside the wheel 513 adjacent to the outer surface 513a of the wheel 513, and extends from the inside of the wheel 513 to the inside of the shaft 512. The cooling flow path 514 passes through the supply flow path FC to which the coolant is supplied, and the supplied cooling water passes through the inside of the shaft 512 to pass through the outer surface 513a of the wheel 513 and the inside of the neighboring wheel 513. It includes a discharge flow path (FC) for discharging the coolant having a temperature rise by performing heat exchange with the outer surface (513a) of the wheel 513 while passing through the circulation flow path (FC) and the circulation flow path (FC).

The coating layer 520 is coated on the outer surface 513a of the cooling wheel 510.

The coating layer 520 is coated on the outer surface 513a of the cooling wheel 510 by using a low temperature spraying method. The coating layer 520 includes an alloy of metal included in the outer surface 513a of the cooling wheel 510 so as to have high chemical affinity with the outer surface 513a of the cooling wheel 510. For example, when the outer surface 513a of the cooling wheel 510 includes copper, the coating layer 520 may include a copper chromium (CuCr) alloy. The melt M ejected from the nozzle 400 is in direct contact with the coating layer 520, and the melt M is instantaneously cooled while contacting the coating layer 520, thereby forming an amorphous fiber from the melt M. In detail, the coolant is supplied along the cooling channel 514 formed inside the cooling wheel 510, and the melt M is ejected from the nozzle 400 in a state in which the cooling wheel 510 rotates itself at high speed. Upon contact with the coating layer 520, the melt M is instantaneously cooled while spreading widely over the coating layer 520. At this time, as the melt M is instantaneously cooled, the crystal state of the material forming the melt M is formed in an amorphous state, whereby the melt M is formed of an amorphous fiber on the coating layer 520. The amorphous fiber formed on the coating layer 520 falls from the cooling wheel 510 as the cooling wheel 510 rotates.

A method of forming the coating layer 520 on the outer surface of the cooling wheel 510 using the above-described low temperature spraying method will be described later.

Hereinafter, a manufacturing method of the cooling wheel unit according to the second embodiment of the present invention will be described.

First, the cooling wheel 510 rotates itself.

Specifically, after the cooling wheel 510 is positioned in the standby state, the cooling wheel 510 is rotated by itself.

Next, the coating layer 520 is coated on the outer surface 513a of the cooling wheel 510 using the low temperature spray method.

 The metal alloy powder is coated on the rotating outer surface 513a of the cooling wheel 510 by being converted into energy required for bonding between the rotating outer surface 513a and the metal alloy powder of the cooling wheel 510 which is a subject. 520 is coated. As such, the metal alloy powder conveyed by the gas injected at supersonic speed through the de Laval nozzle is sprayed to the outer surface 513a of the cooling wheel 510 at a speed close to that of the gas, whereby the metal alloy powder is cooled by the cooling wheel 510. Since the dense metal alloy film is deposited on the outer surface 513a of the cooling wheel 510 by colliding with the outer surface 513a of the surface, the coating layer 520 formed of the dense metal alloy film on the outer surface 513a of the cooling wheel 510 is formed. Is formed. As such, the area of the coating layer 520, which is a metal alloy film deposited on the outer surface 513a of the cooling wheel 510, can be controlled to a desired size by moving the de Laval nozzle from side to side, and the thickness thereof is determined by the moving speed and It can be controlled in proportion to the feeding amount of the metal alloy powder.

When the superalloy metal alloy powder is sprayed at high speed toward the outer surface 513a of the cooling wheel 510 through the de Laval nozzle, the kinetic energy retained by the metal alloy powder is transmitted to the outer surface 513a of the cooling wheel 510. . At this time, the metal alloy powder is finely crushed due to the impact and the deformation occurs at the same time to form a high-density coating layer (520). The coating layer 520 formed in this manner maintains the crystallinity of the metal alloy powder without additional heat treatment, and forms a high density film having excellent bonding force with the outer surface 513a of the cooling wheel 510. In particular, the outer surface 513a of the cooling wheel 510 includes a metal such as copper, and the metal alloy powder includes a metal alloy having a chemical affinity with the outer surface of the cooling wheel 510 such as copper chromium. The coating layer 520 is stably formed on the outer surface 513a of the 510.

As described above, the coating layer 520 is formed on the outer surface 513a of the cooling wheel 510 by using the low temperature spray method.

As described above, the amorphous fiber manufacturing apparatus including the cooling wheel unit 500 according to the first embodiment of the present invention is a cooling wheel that rotates itself using the manufacturing method of the cooling wheel unit according to the second embodiment of the present invention. Since the coating layer 520 formed by the low temperature spraying method is coated on the outer surface 513a of the 510, even if the coating layer 520 is contaminated or worn by the material cooled from the melt M, the existing coating layer 520 is applied. After removing and again using a low temperature spray method, a new coating layer 520 may be easily formed on the outer surface 513a of the cooling wheel 510.

In addition, the manufacturing method of the cooling wheel unit according to the second embodiment of the present invention by rotating the cooling wheel 510 in the state of the cooling wheel 510, the coating layer on the outer surface (513a) of the cooling wheel 510 by a low temperature spray method By forming 520, it is easy to adjust the thickness of the coating layer 520.

In addition, the manufacturing method of the cooling wheel unit according to the second embodiment of the present invention, the support 511, the shaft 512, the wheel 513 and the cooling passage 514 without the need to disassemble or reassemble the cooling wheel 510. Since the coating layer 520 may be formed on the outer surface 513a of the cooling wheel 510 including the low temperature spray method, the maintenance time and the maintenance cost of the cooling wheel unit 500 are reduced. This acts as a factor of reducing the maintenance time and the maintenance cost of the amorphous fiber manufacturing apparatus according to the first embodiment of the present invention.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made therein without departing from the spirit and scope of the following claims. Those who are engaged in the technology field will understand easily.

Cooling Wheel 510, Coating Layer 520

Claims (5)

In the cooling wheel unit for cooling the melt,
Self-rotating cooling wheel; And
The outer surface of the cooling wheel is coated using a low temperature spray method, the coating layer in contact with the melt
Cooling wheel unit comprising a. In claim 1,
The cooling wheel,
A support;
A shaft rotatably supported by the support portion;
A wheel supported on the shaft; And
Cooling flow path formed inside the wheel adjacent to the outer surface of the wheel
Cooling wheel unit comprising a. In claim 1,
The outer surface of the cooling wheel comprises a metal,
The coating layer is a cooling wheel unit comprising an alloy of the metal. In the manufacturing method of the cooling wheel unit which cools a melt,
Self-rotating the cooling wheel; And
Coating a coating layer in contact with the melt on a rotating outer surface of the cooling wheel by using a low temperature spray method;
Method of manufacturing a cooling wheel unit comprising a. A crucible forming a melting space in which the melt is located;
A furnace tube communicating with the melting space and forming a flow path through which the melt passes;
A nozzle in communication with the flow path for ejecting the melt to the outside; And
Cooling wheel unit according to any one of claims 1 to 3
Amorphous fiber manufacturing apparatus comprising a.

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