KR20220081898A - Hybrid apparatus for Fluidized Bed Assisted Abrasive Jet Machining - Google Patents

Abstract

The present invention relates to a hybrid particle fluidized bed processing apparatus capable of grinding the abrasive surface of a workpiece by particle flow. In particular, as the use rate of 3D printers increases, for deburring and polishing of products produced through 3D printers. It relates to a compact hybrid particle fluidized bed processing apparatus.
An object of the present invention is to provide a small hybrid particle fluidized bed processing apparatus for post-processing a 3D printer product output in three dimensions at a research institute or university producing a prototype through a 3D printer.
The present invention has been devised to solve the above problems, and an object of the present invention is to provide a compact hybrid particle fluidized bed processing apparatus capable of improving the surface roughness of the polished surface of a workpiece by equalizing the diameter of abrasive particles. .
In addition, the first rotation shaft and the second rotation shaft are formed so that the workpiece attached to the workpiece mounting unit is polished in various directions.

Description

Hybrid particle fluidized bed processing apparatus {Hybrid apparatus for Fluidized Bed Assisted Abrasive Jet Machining}

The present invention relates to a hybrid particle fluidized bed processing apparatus capable of grinding the abrasive surface of a workpiece by particle flow. In particular, as the use rate of 3D printers increases, for deburring and polishing of products produced through 3D printers. It relates to a compact hybrid particle fluidized bed processing apparatus.

The abrasive fluidized bed machining (AFBM) process was first developed by the Soviet Research Institute for Abrasive and Grinding (VNIIASh) in 1977 under the name turbo-abrasive finishing, and in 2001, It has recently begun to be re-examined as it is applied to the finishing of aluminum casting parts. Since then, the application area has been expanded to finishing and surface cleaning of various types of difficult-to-cut materials.

Particle fluidized bed machining is similar to general abrasive fluidized machining (AFM) in that abrasive machining of the outer and inner surfaces of a three-dimensional shape can be performed by the flow of particles. Machining is performed by the shear force generated by In addition, it is known that the particle fluidized bed machining exhibits a higher material removal rate (MRR) compared to barrel polishing. In addition, the particle fluidized bed processing can be utilized for deburring, polishing, edge contouring, shot peening, and cleaning.

On the other hand, as the use of 3D printers increases, various industrial methods using 3D printers are in progress, and the production of product parts through 3D printers is one of them. When a product produced with a 3D printer is actually used, deburring and polishing of the product is necessary.

Korean Patent Publication No. 10-2183575 (2020.11.20) Korean Patent Registration No. 10-1838712 (2018.03.08)

An object of the present invention is to provide a small hybrid particle fluidized bed processing apparatus for post-processing a 3D printer product output in three dimensions at a research institute or university producing a prototype through a 3D printer.

The present invention has been devised to solve the above problems, and an object of the present invention is to provide a compact hybrid particle fluidized bed processing apparatus capable of improving the surface roughness of the polished surface of a workpiece by uniformizing the diameter of abrasive particles. .

In addition, the first rotation shaft and the second rotation shaft are formed so that the workpiece attached to the workpiece mounting unit is polished in various directions.

In order to solve the above problems, the present invention has an inner chamber 100 having a space for accommodating abrasive particles, the diameter decreases from the top to one side, and the diameter increases from one side to the bottom, and the inside The outer chamber 200 provided to accommodate the chamber 100, the mounting part 300 installed on the upper part to support the first driving part 400 located on one side of the internal chamber 100, and one side of the first mounting part (300) and the other side is connected to the first rotation shaft 500, the first driving part 400 for rotating the first rotation shaft 500, and the first installed to be connected to the first driving part 400 The rotation shaft 500, the connection part 600 connected to the lower end of the first rotation shaft 500, the space in which the second driving part 700 is accommodated is formed, and the connection part 600 is located in the inner space, but One side is connected to the second rotation shaft 800, a second driving part 700 for rotating the second rotation shaft 800, and a second formed having a predetermined length connected to one side of the second driving part 700 A rotating shaft 800, a workpiece mounting part 900 connected to one side of the second rotation shaft 800 for mounting a workpiece, and a first injection nozzle 1000 formed on one side of the inner upper part of the inner chamber 100 And, to provide a hybrid particle fluidized bed processing apparatus, characterized in that it comprises a blower 1200 located at the lower end side of the inner chamber 100, which is formed so that a predetermined number of blades rotate about a central axis of rotation. .

As described above, according to the small particle fluidized bed processing apparatus related to at least one embodiment of the present invention, the cost of the equipment is reduced because the equipment is miniaturized, and the post-processing of the output of the 3D printer through the present invention will be made a lot. . It is expected that the quality of prototypes or parts printed with 3D printers will increase due to post-processing.

1 is a schematic view showing a hybrid particle fluidized bed processing apparatus of the present invention.
2 is a view showing a state inside the inner chamber 100 of the hybrid particle fluidized bed processing apparatus of the present invention.
3 is an enlarged view of the first rotating shaft 500, the second driving unit 700, the second rotating shaft 800, and the workpiece mounting unit 900 of the hybrid particle fluidized bed processing apparatus of the present invention.

The terms or words used in the present specification and claims should not be construed as being limited to conventional or dictionary meanings, and the inventor can properly define the concept of the term to best describe his invention. Based on the principle, it should be interpreted as meaning and concept consistent with the technical idea of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In addition, regardless of the reference numerals, the same or corresponding components are given the same or similar reference numbers, and the overlapping description thereof will be omitted, and the size and shape of each component shown for convenience of description is exaggerated or reduced. can be

The present invention relates to a hybrid particle fluidized bed processing apparatus capable of grinding the abrasive surface of a workpiece by particle flow. In particular, as the use rate of 3D printers increases, for deburring and polishing of products produced through 3D printers. It relates to a compact hybrid particle fluidized bed processing apparatus.

1 is a view showing a hybrid particle fluidized bed processing apparatus (hereinafter referred to as a processing apparatus) of the present invention, wherein the processing apparatus of the present invention includes an inner chamber 100, an outer chamber 200, a mounting unit 300, and a first driving unit ( 400), the first rotation shaft 500, the connection part 600, the second driving part 700, the second rotation shaft 800, the workpiece mounting part 900, the first injection nozzle 1000, the second injection nozzle 1100 , is configured to include a blower 1200 .

Each component is described in detail as follows.

The inner chamber 100 has a space for accommodating the abrasive particles 5, and the diameter decreases from the top to one side, and the diameter increases from one side to the bottom.

2 is a view showing the state of the inner chamber of the small particle fluidized bed processing apparatus according to the present invention.

The inner chamber 100 of the present invention is formed so that the lower end is concave so that the diameter is reduced. It works.

The outer chamber 200 is provided to accommodate the inner chamber 100 .

The mounting part 300 is installed on the upper part to support the first driving part 400 located on one side of the inner chamber 100 .

One side of the first driving unit 400 is connected to the first mounting unit 300 and the other side is connected to the first rotating shaft 500 so that the first rotating shaft 500 rotates.

The first driving unit 400 may be a motor capable of forward rotation or reverse rotation, and a rotation speed may be adjustable.

The first rotating shaft 500 is installed to be connected to the first driving unit 400 .

The connection part 600 is connected to the lower end of the first rotation shaft 500 , and a space in which the second driving part 700 is accommodated is formed.

3 is a view showing the first rotating shaft 500, the second driving unit 700, the second rotating shaft 800, and the workpiece mounting unit 900 of the hybrid particle fluidized bed processing apparatus of the present invention.

The second driving part 700 is located in the inner space of the connection part 600 , but one side is connected to the second rotation shaft 800 so that the second rotation shaft 800 rotates.

The second driving unit 700 may be a motor capable of forward or reverse rotation, and a rotation speed may be adjustable.

The second rotating shaft 800 is formed to have a predetermined length connected to one side of the second driving unit 700 .

As described above, the first rotation shaft 500 and the second rotation shaft 800 are vertically formed and rotated by the first driving part 400 and the second driving part 700, respectively, and as shown in FIG. The workpiece mounting unit 900 mounted on one side may be rotated in a horizontal direction with the ground (S1 direction) and at the same time rotated in a vertical direction with the ground (S2 direction). As such, by rotating in several directions, there is an advantage that the workpiece can be polished evenly by being exposed to the abrasive particles in various directions.

The workpiece mounting part 900 is connected to one side of the second rotation shaft 800 for mounting a workpiece.

The first injection nozzle 1000 is formed on one inner upper side of the inner chamber 100 , and the second injection nozzle 1100 is formed on the other upper inner side of the inner chamber 100 .

The first injection nozzle 1000 and the second injection nozzle 1100 are for spraying a chemical liquid to the processing area, and the chemical liquid sprayed through the injection device may react with the workpiece (specimen) to cause a chemical reaction.

As described above, the present invention is provided to simultaneously perform mechanical polishing using abrasive particles and chemical polishing using a chemical solution to provide a hydride polishing process.

In addition, the first injection nozzle 1000 and the second injection nozzle 1100 may be provided to adjust one or more of the injection amount, the injection direction, and the injection speed of the chemical liquid, and the first injection nozzle 1000 and The second injection nozzle 1100 may be provided with either one of the two or both.

The blower 1200 is located on one side of the lower end of the inner chamber 100 . The blower 1200 is for generating the total air flow in the inner chamber 100 .

In addition, the blower 1200 may be provided so that a predetermined number of blades are formed and rotated about the central axis of rotation so that the central axis of rotation for generating airflow is substantially parallel to the first axis of rotation 500, For example, the blower 1200 may be provided such that the central axis of rotation for generating the airflow is located on the same axis as the first rotation shaft 500 .

As the blower 1200 rotates, an airflow is generated in the abrasive particles contained in the inner chamber 100 to generate a flow of abrasive particles in the inner chamber 100, and accordingly, when the blower 1200 is operated, the abrasive Particles may flow to the workpiece surface.

The configuration shown in the embodiments and drawings described in the present specification as described above is merely the most preferred embodiment of the present invention and does not represent all of the technical spirit of the present invention, so various equivalents and modifications that can be substituted for them It should be understood that there may be examples.

100 inner chamber
200 outer chamber
300 mount
400 first drive unit
500 first rotation axis
600 connections
700 2nd drive unit
800 2nd axis of rotation
900 Workpiece mounting part
1000 1st injection nozzle
1100 2nd injection nozzle
1200 blower

Claims (1)

An inner chamber 100 having a space for accommodating the abrasive particles, the diameter decreases from the top to one side, and the diameter increases from one side to the bottom;
an outer chamber 200 provided to accommodate the inner chamber 100;
a mounting part 300 installed on the upper part to support the first driving part 400 located on one side of the inner chamber 100;
One side is connected to the first mounting part 300 and the other side is connected to the first rotation shaft 500 and a first driving part 400 for rotating the first rotation shaft 500,
a first rotation shaft 500 installed to be connected to the first driving unit 400;
a connection part 600 connected to the lower end of the first rotation shaft 500 and having a space in which the second driving part 700 is accommodated;
A second driving part 700 located in the inner space of the connection part 600, but one side of which is connected to the second rotation shaft 800 so that the second rotation shaft 800 rotates;
a second rotating shaft 800 formed with a predetermined length connected to one side of the second driving unit 700;
and a workpiece mounting part 900 connected to one side of the second rotation shaft 800 for mounting a workpiece;
A first injection nozzle 1000 formed on an inner upper side of the inner chamber 100,
Hybrid particle fluidized bed processing apparatus, characterized in that it comprises a blower (1200) located at the lower end side of the inner chamber (100) to be formed so that a predetermined number of blades rotate around a central axis of rotation.

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