KR102122923B1 - Apparatus for manufacturing a ceramic powder - Google Patents

Abstract

The present invention relates to a device for producing fine-particle ceramic powder using rotation and drop to form ceramic powder. The device comprises: a support frame; a control unit formed on the support frame to control a rotation speed and time of a motor; a worm gear reducer on the side of the support frame; a handle controlling the worm gear reducer; an outer case; a ceramic container inside the outer case; a rotating body surrounding the ceramic container; an outer lid unit having a ceramic plate formed therein so as to seal the upper portion of the outer case; an upper central shaft formed on the center of the lower portion of the rotating body; a waist central shaft formed to fix the center of the outer case; a connection coupler connecting a motor shaft to the upper central shaft; and a motor unit configured to rotate the motor shaft by receiving external power. The rotating body is rotated in the outer case, and the outer case is connected to the waist central shaft of the outer case so that the motor unit changes its direction from vertical to horizontal to rotate the worm gear reducer by a handle. Accordingly, workers can conveniently produce finely divided ceramics.

Description

Apparatus for manufacturing a ceramic powder for high-purity dental tools

The present invention relates to an apparatus for manufacturing a high-purity dental tool ceramic powder, and more particularly, to a device for manufacturing a fine-powdered ceramic powder using a rotational speed by inserting a processed ceramic powder and steel wire to form a high-purity ceramic powder. It is about.

In the case of the nanocomposite technology of ceramics, it is difficult to refine the coarse ceramic particles to the nano-size technically with the existing MA method, and the expensive nano ceramic powder (several nm) is milled in a metal or alloy base for a long time to disperse the strengthened alloy Powder is being prepared. For example, mechanical alloying is performed for 48 hours at a speed of 220 rpm in an attritor using a Y2O3 powder of about 20 nm and a mixed powder of Fe-Cr for the manufacture of ferrite steel for oxide dispersion-reinforced for application of nuclear power plants. One result was reported (S. Ukai, S. Mizuta, T. Yoshitake, T. Okuda, M. Fujiwara, S. Hagi, T. Kobayashi, J. Nuclear Materials, 283-287 (2000) 702), Fe- It has been reported that mechanical alloying was performed for 16 hours at 500 rpm using a planetary ball mill (Retsch PM200) to disperse a 20 nm-sized Y2O3 powder for Ni-Cr ternary alloy steel.

However, most conventional ball milling processes have low milling speed and low milling energy, so it is inefficient to mill for a long time for several tens of hours for uniform alloying, and the temperature of the powder container during the long alloying process is about 100-220℃. There is a problem, such as a large rise. In addition, when manufacturing nano-ceramic composite materials such as oxide dispersion-reinforced alloys, it is necessary to use expensive dozens of nano-sized powders for the initial ceramic raw material powder, resulting in an increase in manufacturing costs caused by the use of expensive and expensive materials, resulting in a variety of component materials industries. There is a problem that is difficult to apply.

Thus, by applying a high milling speed and high energy milling technology, as well as simultaneously realizing metal-metal alloying and nanocompositing of ceramic powder in a short time compared to the conventional milling process, nano ceramic dispersion strengthening with a very uniform and fine structure A method for producing alloy/metal powder was developed.

1.Korea Patent Office Patent Registration No. 1106650 (2012.01.10) 2. Korea Patent Office Patent Registration No. 1101243 (2011.12.26)

The problem to be solved of the present invention

Provides a high-purity dental tool ceramic powder manufacturing device that can be used for dental tools using finely divided powder by pulverizing the ceramic powder due to friction with steel when rotating with a rotary motor after putting ceramic powder together with steel It has its purpose.

An object of the present invention is to provide a high-purity dental tool ceramic powder manufacturing apparatus having a structure in which the micronized ceramic is rotated to a desired position during processing and has a convenient discharge after processing.

Means for solving the problems of the present invention

A control unit formed on the support frame and the support frame to control the rotational speed and time of the motor; A handle for controlling the worm gear reducer and the worm gear reducer on the side surface of the support frame; A ceramic cylinder and a rotating body surrounding the ceramic cylinder inside the outer case and the outer case; An outer lid portion formed with a ceramic inside to seal the upper portion of the outer case; A connecting coupler connecting a motor shaft to the upper central shaft and the upper central shaft at the center of the lower portion of the rotating body; A motor unit formed to rotate the motor shaft by receiving external power; It was achieved so that the rotating body is rotated in the outer case and the outer case is made of a handle including a worm gear reducer formed on a side axis of the outer case so that the motor part changes direction from a vertical direction to a horizontal direction.

High-purity dental tool ceramic powder manufacturing apparatus of the present invention

As a device for obtaining high-purity powder, if ceramics and steel to be processed are put into rotation to produce high-purity powder ceramics, and then rotated, the steel and ceramic powders collide and the ceramic powder is finely powdered. have.

In addition, it is convenient to put the ceramic and steel to be processed in a vertically standing state, and can be flipped over and removed after processing, so that the user can conveniently enter and exit before and after processing.

The present invention is a very useful invention that is formed so as to increase the contact force between the steel and the ceramic by forming a structure using a separating inside by forming a separating type guide protrusion inside.

1 is a perspective view showing a high-purity dental tool ceramic powder manufacturing apparatus of a preferred embodiment of the present invention.
Figure 2 is a state of use of the high-purity dental tool ceramic powder manufacturing apparatus of the present invention.
Figure 3 is a side view showing a high-purity dental tool ceramic powder manufacturing apparatus of the present invention.
Figure 4 is a front view of the high-purity dental tool ceramic powder manufacturing apparatus of the present invention.
Figure 5 is a state of use of the high-purity dental tool ceramic powder manufacturing apparatus of the present invention.
Figure 6a and Figure 6b is a state diagram showing the lid portion of the high-purity dental tool ceramic powder manufacturing apparatus of another embodiment of the present invention.

Advantages and features of the present invention, and methods for achieving them will be clarified with reference to embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only these embodiments make the disclosure of the present invention complete, and those skilled in the art to which the present invention pertains. It is provided to fully inform the scope of the present invention to the present invention, and the present invention is only defined by the scope of the claims.

The terminology used herein is for describing the embodiments and is not intended to limit the present invention. In the present specification, the singular form also includes the plural form unless otherwise specified in the phrase. As used herein, "comprises." And/or “comprising” does not exclude the presence or addition of one or more other components other than the components mentioned. Throughout the specification, the same reference numerals refer to the same components, and “and/or” includes each and every combination of one or more of the components mentioned. Although "first", "second", etc. are used to describe various components, it goes without saying that these components are not limited by these terms. These terms are only used to distinguish one component from another component. Therefore, it goes without saying that the first component mentioned below may be the second component within the technical spirit of the present invention.

Unless otherwise defined, all terms (including technical and scientific terms) used in the present specification may be used as meanings commonly understood by those skilled in the art to which the present invention pertains. In addition, terms defined in the commonly used dictionary are not ideally or excessively interpreted unless explicitly defined.

High-purity dental tool ceramic powder manufacturing apparatus of the present invention

A support frame 200 and a control unit 300 formed on the support frame to control the rotational speed and time of the motor; On the side of the support frame, a worm gear reducer 400 and a handle 410 for controlling the worm gear reducer; An outer case 510 and a ceramic cylinder 520 and a rotating body 500 surrounding the ceramic cylinder inside the outer case; An outer lid part 100 having a ceramic plate 120 formed therein to seal the upper portion of the outer case; An upper center shaft 210 formed in the center of the lower portion to rotate the rotating body: a waist center shaft 230 formed to fix the center of the outer case; A connecting coupler 220 connecting the motor shaft 240 to the upper central shaft 210; A motor unit 250 formed to rotate the motor shaft 240 by receiving external power; In the outer case, the rotating body 500 is rotated and the outer case and the motor part are connected to the waist center shaft 230 of the outer case and the worm gear reducer to change the direction from the vertical direction to the horizontal direction. It is formed to rotate to 410, and when the power of the control unit is turned on, the motor unit 250 is rotated by an external power source so that the rotating body 500 is rotated to form ceramic powder and steel in the rotating body. It is characterized in that they collide with each other to form a ceramic differential.

Ceramics and steels to be processed are contained in the rotating body 500 so that the rotating body is rotated to form a fine ceramic.

The control unit 300 controls the rotation speed of the motor unit 250 to obtain a desired size of the ceramic particles. The control unit 300 is formed to control the rotation and operating time of the motor unit is provided with an on/off switch, an operating time adjusting unit and a rotation speed adjusting unit.

The outer case 510 and the outer lid part 100 are formed to be fixed or loosened with a fastening bolt 330 and a nut 340.

When the handle 410 is rotated, the powder generating unit 600 including the outer case and the rotating body is rotated with a rotational force decelerated to the worm gear reducer 400 to form a horizontal state, and the worm gear reducer to maintain the horizontal state It is characterized in that the horizontal holding pin 320 is inserted into the fixture 310 to prevent rotation.

The horizontal holding pin 320 was inserted and fixed to rotate the handle to fix the powder generating part 600 and the motor part horizontally and vertically or after a desired position.

When the motor part 250 is rotated in the horizontally maintained state, the rotating body 500 rotates, and the steel 180 and the ceramic particles 190 collide with each other to form fine powder.

After the micronization is completed as described above, the nut 340 connected to the bolt 330 is released, and the outer lid 110 is opened to check and discharge.

In another embodiment of Figures 6a, 6b of the present invention is formed to evenly agitate inside, but forming a seating groove 390 in the center of the formed ceramic plate 120 of the outer lid portion 110 and the seating groove 390 The ceramic mixing cylinder portion 360 is formed, the ceramic mixing cylinder portion 360 is formed with a mounting groove 370 on the side, and the mounting groove has a feature in which a protruding substrate 380 is formed.

It is characterized in that the ceramic particles 180, which are drooped at the bottom, can be mixed with the steel 190 without increasing the rotational speed in the horizontally maintained state as described above.

At this time, the rotating body 500 rotates, but since it is fixed to the outer lid portion 110, the ceramic particles are sufficiently mixed.

100: lid 110: handle
120: ceramic lid 200: support frame
210: upper center axis 220: connecting coupler
230: waist center axis 240: motor shaft
250: motor part 300: ceramic barrel
310: fixture 330: bolt
340: nut 400: worm gear reducer
410: handle 420: horizontal holding pin
500: rotating body 600: powder generating unit

Claims (3)

A support frame 200 and a control unit 300 formed on the support frame to control the rotational speed and time of the motor; On the side of the support frame, a worm gear reducer 400 and a handle 410 for controlling the worm gear reducer; An outer case 510 and a ceramic cylinder 520 and a rotating body 500 surrounding the ceramic cylinder inside the outer case; An outer lid part 100 having a ceramic plate 120 formed therein to seal the upper portion of the outer case; An upper center shaft 210 formed at the center of the lower portion to rotate the rotating body: a waist center shaft 230 formed to fix the center of the outer case; A connecting coupler 220 connecting the motor shaft 240 to the upper central shaft 210; A motor unit 250 formed to rotate the motor shaft 240 by receiving external power; The worm gear reducer is connected to the waist center shaft 230 of the outer case and the worm gear reducer so that the rotating body 500 is rotated in the outer case and the outer case and the motor part change direction from vertical to horizontal. 410), and when the power of the control unit is turned on, the motor unit 250 is rotated by an external power source, so that the rotating body 500 is rotated so that the ceramic powder and steel in the rotating body are rotated. High-purity dental tool ceramic powder manufacturing apparatus, characterized in that to form a ceramic powder by hitting each other.
The method of claim 1, wherein when the handle 410 is rotated, the powder generating part (600) including the outer case and the rotating body is rotated with the decelerated rotational force to the worm gear reducer (400) to form a level, and the horizontal High-purity dental tool ceramic powder manufacturing apparatus characterized in that it is formed to be fixed at an angle of the current position by inserting a horizontal holding pin 320 into the fixture 310 of the worm gear reducer to maintain the state.
The method of claim 1, wherein the outer lid portion 100 is
A seating groove 390 is formed in the center of the ceramic rack 120, and a ceramic stirring cylinder 360 is fixed to the seating groove 390, and the ceramic stirring cylinder 360 is mounted on the side. High-purity dental tool ceramic powder manufacturing apparatus characterized by forming a groove (370), a plurality of projection substrates (380) formed in the mounting groove.

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