KR102336852B1 - Metal Powder Cooling Device and Method Thereof - Google Patents

Abstract

The present invention relates to a metal powder cooling apparatus and method capable of cooling a metal base material formed of titanium after melting with plasma. A cooling device for cooling and a processing device for processing the base material powder cooled by the cooling device into a spherical shape are provided.

Description

Metal Powder Cooling Device and Method Thereof

The present invention relates to a metal powder cooling apparatus and method capable of cooling a metal base material formed of titanium after melting with plasma.

Patent Document 001 discloses a blower configured to supply a gas for cooling a plated layer of a plated steel sheet plated with molten metal; a gas injection nozzle connected to the blower and configured to jet the gas supplied from the blower to the plated steel sheet; and a permanent magnet disposed adjacent to the gas injection nozzle to form a magnetic force line flowing into the plated steel sheet, and a high-speed cooling device for a molten metal plating facility of the present invention according to another aspect for solving the above problems, including a molten metal a blower configured to supply a gas for cooling the plated layer of the plated plated steel sheet; a gas injection nozzle connected to the blower and configured to jet the gas supplied from the blower to the plated steel sheet; a permanent magnet disposed adjacent to the gas injection nozzle to form a magnetic force line flowing into the plated steel sheet; and an iron core fixedly installed on the permanent magnet to form a passage through which the magnetic force lines can flow smoothly.

Patent Invention 002 discloses that a predetermined space is formed inside an insulating furnace body, and a graphite crucible equipped with a rotary stir bar and a thermocouple or thermocouple for measuring the temperature of the molten metal is installed in the space. Slurry cooling for high temperature viscosity measurement of metal In the apparatus, an air supply means is installed in the inside of the heat insulating furnace to inject cooling air supplied from the outside, and the crucible is made of pure graphite having superior thermal conductivity compared to metal.

Patent Invention 003 is an injection cooling unit that sprays a cooling medium on the surface of a metal material; and an injection angle adjustment unit connected to the injection cooling unit and adjusting the injection angle of the cooling medium injected from the injection cooling unit according to the width of the metal material, wherein the injection angle adjustment unit includes the injection of the cooling medium an injection nozzle plate in which at least a portion of a flow path through which the cooling medium moves is variable so that the angle is adjusted; and a driving member for driving the injection nozzle plate to change a flow path through which the cooling medium moves, wherein the injection nozzle plate is installed in a front central region of the injection cooling unit to spray the cooling medium in the front direction. central nozzle plate; and a laminated nozzle plate disposed on both sides of the central nozzle plate and in which a plurality of laminated plate members driven by the driving member are stacked in multiple stages to adjust the injection angle in the width direction of the cooling medium toward the transferred metal material; The available technologies are presented.

Patent Invention 004 discloses at least two metal strips disposed opposite to each other with a metal strip continuously transferred in the longitudinal direction interposed therebetween, each of which is attached to a blower box for cooling gas and includes nozzles facing toward the surface of each strip. A metal strip cooling device for cooling a metal strip comprising a nozzle field and a flow conduit disposed between the nozzles for discharging cooling gas coming out of the nozzle and deflecting on the strip surface, the metal strip cooling device comprising: a gas conduit connected to a blower box; On the other hand, in the nozzle strips arranged adjacent to each other at regular intervals in parallel, the nozzles are coupled together in a group form and at the same time include nozzle openings facing each metal strip surface and are distributed over the length of the nozzle strip, cooling A technique is presented in which a flow conduit for evacuating a gas stream is disposed between nozzle strips extending transverse to the blast box.

KR 10-2010-0074979 A (July 02, 2010) KR 10-2001-0059704 A (July 06, 2001) KR 10-1819386 B1 (January 10, 2018) KR 10-2008-0037003 B1 (April 29, 2008)

The present invention relates to a metal powder cooling apparatus and method capable of cooling a metal base material formed of titanium after melting with plasma.

In order to solve the problems of the prior inventions, the present invention is an invention for a metal powder cooling device, specifically a melting device 100 for melting the base material 10; a base material melted by the melting device 100 A cooling device 200 for cooling the powder 20; A processing device 300 for processing the base material powder 20 cooled by the cooling device 200 into a spherical shape;

The present invention is an invention for a metal powder cooling device, and is formed in the cooling device 200 in the invention comprising the above-mentioned melting device 100; cooling device 200; processing device 300; An inlet case 210 into which the base material powder 20 is introduced, and a cooling water 220 accommodated in the inlet case 210 and cooling the base material powder 20; is added.

The present invention is an invention for a metal powder cooling device, and is formed in the processing device 300 in the invention consisting of the above-mentioned melting device 100; the cooling device 200; and the processing device 300; an input case 310 into which the base material powder 20 is put; A blade 320 formed inside the input case 310 and processed by rotating the base material powder 20; is added.

The present invention is an invention for a metal powder cooling device, and is formed at the lower end of the processing device 300 in the invention comprising the above-mentioned melting device 100; cooling device 200; processing device 300; , a classification device 400 for classifying the base material powder 20 by size; is added.

The present invention is an invention for a metal powder cooling method, and in the invention presented above, a melting step (S1100) of melting the base material 10 in the melting apparatus 100;, after the melting step (S1100), the base material powder 20 ) cooling step (S1200); After the cooling step (S1200), processing step (S1300) of processing the base material powder (20); After the processing step (S1300), the classification step (S1400) of classifying the base material powder 20; consists of a configuration including a.

According to the present invention, a uniform shape can be maintained by being sprayed by being generated as a base material powder as the molten base material is sprayed.

The present invention can increase the strength of the base material by rapidly cooling the base material.

The present invention can produce a uniform base material powder by controlling the temperature of the cooling water.

The present invention can be produced in a perfect spherical shape by processing the base material powder.

The present invention can remove particles by generating friction between the base material powder by the blade.

The present invention can classify the base material powder by size by a classification device.

1 is a cross-sectional view showing a metal powder cooling device of the present invention.
Figure 2 is a cross-sectional view showing the melting apparatus of the present invention.
3 to 5 are cross-sectional views showing the processing apparatus of the present invention.
6 to 8 are cross-sectional views showing the classification device of the present invention.
9 is a flowchart illustrating a method for cooling a metal powder according to another embodiment of the present invention.

Hereinafter, the most preferred embodiment of the present invention will be described in detail in order to explain in detail enough that a person of ordinary skill in the art to which the present invention pertains can easily carry out the present invention.

The numbers cited in the examples below are not limited only to the objects of reference, and may be applied to all examples. An object that exhibits the same purpose and effect as the configuration presented in the embodiment corresponds to an equivalent replacement object. The higher-level concept presented in the examples includes sub-concept objects that are not described.

(Example 1-1) In the present invention, in a metal powder cooling device, a melting device 100 for melting the base material 10; cooling the base metal powder 20 melted by the melting device 100 a cooling device 200; and a processing device 300 for processing the base material powder 20 cooled in the cooling device 200 into a spherical shape.

(Example 1-2) In the metal powder cooling apparatus of the present invention, in Example 1-1, the melting apparatus 100 includes a base material supply unit 110 to which the base material 10 is supplied; and the base material supply unit 110 a gas ejection unit 120 formed on one side of the at least one gas; and a plasma generating unit 130 formed in the base material supply unit 110 and generating plasma by mixing current and gas.

(Example 1-3) The metal powder cooling apparatus of the present invention is in Example 1-2, wherein the base material supply unit 110 includes a supply chamber 111 in which the base material 10 is accommodated; and extends to the plasma generator and a supply body 112 to which the base material 10 is supplied.

The present invention relates to a metal powder cooling device, specifically to cool a metal powder melted by plasma. The metal to be cooled in such a metal powder cooling device is variously formed such as titanium (ti), tungsten, molybdenum, nickel, and the like, and a material that is difficult to process due to its high strength is processed into the base material powder 20 by using plasma. In general, the high-strength base material 10 such as titanium has a problem in that it is difficult to form, so it is processed into a powder and attached or used in a 3D printer. Such a base material 10 is formed in a cylindrical shape like an ingot or is formed in a cartridge type to move, and is melted and processed by plasma. This base material 10 is melted in the melting device 100 and processed into powder, and is supplied from the base material supply unit 110, and the base material supply unit 110 is a supply chamber in which the base material 10 formed of a cartridge and a winding roll is accommodated ( 111) and the supply chamber 111 and the supply body 112 for connecting the plasma generator is formed. And in another embodiment, the base material supply unit 110 has a liquid chamber to which the liquid base material 10 is supplied, and a through chamber through which the base material 10 formed of an ingot passes through the gas ejection unit 120 . The plasma generating unit 130 supplies a current to the base material 10 and the supply body 112 so that the current moves, and plasma is generated by the gas ejected from the gas ejection unit 120 . Accordingly, the end of the base material 10 is melted by the generated plasma, and the gas stored in the gas ejection unit 120 is ejected by the ejection device to generate plasma and at the same time the molten base material 10 is sprayed and descended. will do The cooling device 200 is formed so that the descending base material powder 20 is cooled to maintain its strength, and a processing device 300 is formed at the lower end of the cooling device 200 and attached to the base material powder 20 It is to be processed into a spherical shape by removing the old particles (30).

Therefore, the metal powder cooling device of the present invention has a feature of forming the base material powder 20 by cooling and processing the base material 10 molten by plasma is sprayed and descends.

(Example 2-1) The present invention relates to a metal powder cooling device, and in Example 1-1, an inflow case 210 formed in the cooling device 200 and into which the base material powder 20 flows. ;, is accommodated in the inlet case 210, the cooling water 220 for cooling the base material powder (20); includes.

(Embodiment 2-2) The metal powder cooling device of the present invention is the vibrating device of Example 2-1, wherein the cooling device 200 removes foreign substances from the coolant 220 and the base material powder 20 ( 211);, including.

(Embodiment 2-3) The metal powder cooling device of the present invention is the embodiment 2-2, wherein the inlet case 210 includes an inlet hole 230 through which the cooling water 220 flows; and the cooling water 220 a discharge hole 240 through which is discharged; and an opening/closing valve 250 for opening and closing the inlet hole 230 and the discharge hole 240 .

(Embodiment 2-4) In Embodiment 2-3, the metal powder cooling device of the present invention includes: a temperature control device 260 formed in the inlet case 210 to control the temperature of the cooling water 220; includes

The present invention relates to a cooling device 200 , and specifically, the cooling device 200 cools the base metal powder 20 molten at a high temperature by plasma. The cooling device 200 has an inlet case 210 into which the base material powder 20 flows, and the cooling water 220 is accommodated in the inlet case 210 . The inlet case 210 is formed at the lower end of the melting apparatus 100, and the base material powder 20 injected by the gas is introduced. And the inlet case 210 is formed in a cone shape with a narrow lower end, and induces the cooled base material powder 20 to be concentrated to the lower end. In this case, the inlet case 210 has an inlet hole 230 through which the cooling water 220 is introduced, and an outlet hole 240 through which the cooling water 220 is discharged, is formed at the lower end. In addition, an on/off valve 250 is formed in the inlet hole 230 and the outlet hole 240 to control the inflow or discharge of the cooling water 220 . In addition, the inlet case 210 has a vibration device 211 formed therein, and the vibration device 211 applies high-wavelength vibration to the cooling water 220 to partially remove the particles 30 of the base material powder 20 and at the same time to remove the cooling water. Remove the foreign substances in (220). In addition, the inlet case 210 is provided with a temperature control device 260 , and the temperature of the cooling water 220 is controlled by the temperature control device 260 . As the temperature of the cooling water 220 is increased by the base material powder 20 melted at a high temperature by plasma, the temperature of the cooling water 220 must be maintained constant.

Accordingly, the cooling device 200 is formed at the lower end of the melting device 100, and has a feature of cooling the base material powder 20 in which the base material 10 is melted by high-temperature plasma.

(Example 3-1) The present invention relates to a metal powder cooling device, and in Example 2-1, the input case 310 is formed in the processing device 300 and into which the base material powder 20 is put. ; It is formed inside the input case 310, and the blade 320 for processing by rotating the base material powder 20; includes.

(Example 3-2) In Example 3-1, the metal powder cooling device of the present invention is formed under the input case 310 and separated from the cooling water 220 and the base material powder 20 and a transmission plate 311 passing through the particles 30 .

(Embodiment 3-3) The metal powder cooling apparatus of the present invention according to Embodiment 3-2, wherein the input case 310 is formed to be inclined.

(Embodiment 3-4) In Embodiment 3-3, the metal powder cooling apparatus of the present invention includes: a rotating shaft 321 formed on the blade 320 and rotated by a motor; It is formed at the end of the rotation shaft 321, the processing plate 322 for processing the base material powder 20; includes.

(Embodiment 3-5) The metal powder cooling apparatus of the present invention according to Embodiment 3-4, wherein the blades 320 are formed in plurality and rotate to cross each other.

The present invention relates to a processing apparatus 300 , and specifically, the processing apparatus 300 removes the particles 30 by processing the base material powder 20 to which the particles 30 are attached. In general, when the base material 10 is melted and sprayed at a high temperature, the base material powder 20 is formed in various sizes and has a spherical shape. In addition, the spherical base material powder 20 having various sizes is formed to overlap each other, and fine particles 30 are attached to the base material powder 20 so that the spherical shape is not maintained. In this way, the processing device 300 includes an input case 310 into which the cooling water 220 supplied from the cooling device 200 and the base material powder 20 are put, and a base material powder 20 formed in plurality in the input case 310 . ) is formed with a blade 320 that rubs against each other. The input case 310 is formed at the lower end of the cooling device 200 , and the transmission plate 311 is formed at the same position as the lower end of the cooling device 200 to transmit the cooling water 220 and the particles 30 . This input case 310 is formed to be sealed, is formed to be inclined or formed horizontally. In addition, a through chamber to which the cooling water 220 and the particles 30 passing through the input case 310 are supplied is formed at the lower end of the transmission plate 311 . The through-chamber separates the cooling water 220 and the particles 30 from each other and discharges them, and the cooling water 220 is circulated by a classification device 400 to be described later and re-supplied to the cooling device 200 . In addition, a plurality of blades 320 are formed in the input case 310 , and the blades 320 are formed to cross each other so that the base material powder 20 transferred to one end of the input case 310 is rubbed in a plurality or the blades 320 . ) and friction to separate the base material powder 20 from each other. The blade 320 has a rotation shaft 321 that rotates by a motor, and the rotation shaft 321 has a plurality of processing plates 322 formed to move the base material powder 20 and induce friction with each other at the same time. do.

Accordingly, the processing device 300 separates the base material powder 20 cooled by the cooling device 200 from each other, and removes the particles 30 to process the powder into a spherical shape.

(Example 3-6) The metal powder cooling apparatus of the present invention includes, in Example 3-1, wherein the input case 310 is formed in a cylindrical shape, and the blade 320 rotates at the center. .

The present invention relates to an input case 310 , and specifically, the input case 310 is formed in a cylindrical shape, and a blade 320 is provided in the center to process the base material powder 20 . In this input case 310, a transmission plate 311 is formed at the lower portion, the cooling water 220 is discharged, and the base material powder 20 is rubbed against each other by the blade 320 to separate the base material powder 20 and particles at the same time. (30) is removed.

(Example 3-7) In the metal powder cooling device of the present invention, in Example 3-1, the input case 310 includes an input part 312 into which the base material powder 20 is input; and the input part ( It is formed on the outside of the 312, the rotating part 314 for rotating the input part 312; includes.

(Example 3-8) In Example 3-3, in the metal powder cooling device of the present invention, the input unit 312 has a plurality of penetration holes 313 through which the cooling water 220 and the particles 30 are transmitted. ); includes.

The present invention relates to the input case 310, and specifically, the input case 310 is formed in a double so that the base material powder 20 collides with each other and separates as the input case 310 inside rotates. The input case 310 has an inner case and an outer case, and the inner case and the outer case are spaced apart from each other. And the inner case is rotated by a motor, and a through hole 313 is formed in the lower part, so that when the inner case rotates, the cooling water 220 and the particles 30 are discharged. In addition, the inner case has friction protrusions 315 formed on its inner circumferential surface so that when the inner case rotates, the base material powder 20 collides with each other and at the same time collides with the friction protrusions 315 to separate the base material powder 20 .

(Example 4-1) The present invention relates to a metal powder cooling device, and in Example 3-1, it is formed at the lower end of the processing device 300 and classifies the base material powder 20 by size device 400;

(Example 4-2) In the metal powder cooling device of the present invention, in Example 4-1, the classifying device 400 permeates the cooling water 220 and a first classifying unit that classifies the base material powder 20 ( 410);, a second classifying unit 420 that filters the base material powder 20 larger than the first classifying unit 410; a third classifying unit that filters the base material powder 20 larger than the second classifying unit 420 part 430;

(Example 4-3) In the metal powder cooling device of the present invention, in Example 4-2, the classifying device 400 is formed in an oblique line so that the unclassified base material powder 20 gathers to one side; include

(Example 4-4) In Example 4-3, the metal powder cooling device of the present invention, the classifying device 400 includes an impact device that generates an impact in order to transmit the base material powder 20;

The present invention relates to a classifying device 400, and specifically, classifying the base material powder 20 processed in the processing device 300 by size. In the classification apparatus 400 of the present invention, a classification plate for classifying the processed base material powder 20 by size is formed, and the classification plate is formed in various ways such as a mesh and a filter. The classification apparatus 400 is formed of a first classification unit 410 , a second classification unit 420 , and a third classification unit 430 , but the number of classifications is not limited. This sorting device 400 makes the sizes of the sorting holes of the first classifying unit 410, the second classifying unit 420, and the third classifying unit 430 different, and the base material powder transmitted from the first classifying unit 410 is different. (20) is prevented from being transmitted in the second classification unit 420 . The first classification unit 410, the second classification unit 420, and the third classification unit 430 are formed in an oblique line, so that the cooling water 220 and the particles 30 are transmitted downward, but the base material powder 20 is in one direction. transmit In this case, the first classifying unit 410 , the second classifying unit 420 , and the third classifying unit 430 are formed in oblique lines to face different directions. This delivers the base material powder 20 by size toward the storage tank formed in each classification device 400 . And the cooling water 220 stored at the lower end of the classifying device 400 is circulated and delivered to the cooling device 200 , and the particles 30 are circulated to be melted again by plasma. In addition, the classifying device 400 may generate an impact to the classifying device 400 so that an impact device is formed so that the base material powder 20 is accumulated and does not interfere with the penetration of the cooling water 220 .

Accordingly, the classifier 400 classifies the pulverized base material powder 20 to classify the base material powder 20 having a size different from that of the cooling water 220 .

(Example 4-5) The metal powder cooling device of the present invention is the example 4-1, wherein the classifying device 400 is formed in the cooling device 200, and the filtering device 440 is formed so that both sides thereof are inclined. ); includes.

(Example 4-6) In Example 4-5, the metal powder cooling device of the present invention, the filtering device 440 includes a filtering hole 450 that is formed differently in size from the outside toward the center. .

(Example 4-7) In Example 4-6, the metal powder cooling device of the present invention is formed at the lower end of the filtering device 440 and separated according to the size of the filtering hole 450 ( 460);

The present invention relates to a classifying device 400 , and specifically, the classifying device 400 is formed at the lower end of the cooling device 200 so that the base material powder 20 descends by classification. In this sorting device 400 , the filtering device 440 is formed at the lower end of the cooling device 200 , and the filtering device 440 rises from the center toward the outside. In addition, the filtering device 440 is formed to have different sizes of the filtering holes 450 at the outside and the center, and the filtering holes 450 are divided into a plurality of types. In addition, a separating plate 460 is formed at the lower end of the filtering device 440 , and the separating plate 460 is formed to extend to the processing device 300 . At this time, a valve is formed at the lower end of the separation plate 460 for each size of the base material powder 20 , and each is processed differently for each size of the base material powder 20 . Specifically, when the base material powder 20 introduced into the cooling water 220 of the cooling device 200 generates a vortex in the cooling water 220 , it descends along the inner wall of the cooling device 200 . At this time, the base material powder 20 is concentrated from the outside to the center in the filtering device 440, and the base material powder 20 according to the size of the filtering hole 450 when the base material powder 20 is moved in the filtering device 440. it is penetrated And the penetrating base material powder 20 is separated by size and descends.

(Example 5-1) The present invention relates to a method for cooling metal powder, a melting step (S1100) of melting the base material 10 in the melting apparatus 100 of Example 1-1 (S1100); the melting step (S1100) Then, a cooling step of cooling the base material powder 20 (S1200); After the cooling step (S1200), processing step (S1300) of processing the base material powder (20); After the processing step (S1300), a classification step (S1400) of classifying the base material powder 20; includes.

10: base material 20: base material powder
30: particle 100: melting device
110: base material supply unit 111: supply chamber
112: supply 120: gas outlet
130: plasma generating unit 200: cooling device
210: inlet case 211: vibration device
220: coolant 230: inlet hole
240: discharge hole 250: on/off valve
260: temperature control device 300: processing device
310: input case 311: transmission plate
312: input unit 313: through hole
314: rotating part 315: friction protrusion
320: blade 321: axis of rotation
322: processing plate 400: sorting device
410: first classification unit 420: second classification unit
430: third classification unit 440: filtering device
450: filtering hole 460: separating plate
S1100: melting step S1200: cooling step
S1300: processing step S1400: sorting step

Claims (5)

Melting device 100 for melting the base material 10;
A cooling device 200 for cooling the base material powder 20 melted by the melting device 100;
Processing the base material powder 20 cooled in the cooling device 200 into a spherical shape
processing device 300;
The melting apparatus 100 includes a base material supply unit 110 to which the base material 10 is supplied;
It is formed on one side of the base material supply unit 110, and at least one gas is ejected.
Gas ejection unit 120;
A plasma generating unit 130 formed in the base material supply unit 110 and generating plasma by mixing current and gas;
The inlet case 210 is formed in the cooling device 200, the base material powder 20 is introduced;
Cooling water 220 accommodated in the inlet case 210 and cooling the base powder 20;
The cooling device 200 removes foreign substances from the cooling water 220 and the base material powder 20 .
Vibration device 211 to remove;
The inlet case 210 has an inlet hole 230 through which the coolant 220 is introduced;
Discharge hole 240 through which the cooling water 220 is discharged;
an on/off valve 250 for opening and closing the inlet hole 230 and the outlet hole 240;
An input case 310 formed in the processing device 300 and into which the base material powder 20 is put;
A plurality of blades 320 are formed inside the input case 310 to rotate to cross each other, and to rotate and process the base material powder 20;
A rotating shaft 321 formed on the blade 320 and rotated by a motor;
A processing plate 322 formed at the end of the rotation shaft 321 and processing the base material powder 20;
A classification device 400 formed at the lower end of the cooling device 200 and the lower end of the processing device 300 and classifying the base material powder 20 by size;
The classification device formed at the lower end of the cooling device 200 includes a filtering device 440 formed so that both sides thereof are inclined;
The filtering device 440 has a filtering hole 450 that is formed differently in size from the outside toward the center;
A metal powder cooling device comprising a; is formed at the lower end of the filtering device (440) and separated according to the size of the filtering hole (450).
delete delete delete In the metal powder cooling method,
A melting step of melting the base material 10 in the melting apparatus 100 of claim 1 (S1100);
After the melting step (S1100), a cooling step (S1200) of cooling the base material powder (20);
After the cooling step (S1200), the processing step of processing the base material powder 20 (S1300);,
After the processing step (S1300), a classification step (S1400) of classifying the base material powder (20);
The melting step (S1100) is a base material supply step of supplying a base material;
Gas ejection step of ejecting gas to one side of the supplied base material;
Plasma generating step of causing a current to move in the base material 10, and generating plasma by mixing the current and gas;
The cooling step (S1200) is a cooling water cooling step in which the base material 10 and the cooling water 220 are introduced into the inlet case 210 to cool the base material 10;
a foreign material removal step of removing foreign substances from the cooling water 220 and the base material powder 20 by applying high-wavelength vibration to the cooling water 220;
a cooling water inflow step of introducing cooling water into the inflow case 210;
A cooling water discharge step of discharging the cooling water 220 of the inlet case 210;
a cooling water inflow and outflow control step of controlling the inflow and discharge amount of the cooling water 220 flowing in and out of the inflow case 210;
In the processing step (S1300), the plurality of blades 320 rotate to cross each other to rotate the base material powder and process the base material powder 20, but the base material is processed through the processing plate 322 formed at the end of the blade 320. Processed in a spherical shape,
The metal powder cooling method, characterized in that the base material powder 20 cooled in the cooling step (S1200) is processed in the processing step (S1300) after classifying it according to size.

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