KR101418555B1 - Chamber for an aerodynamic levitator - Google Patents

Abstract

The present invention relates to a chamber for a gas lifting apparatus, and more particularly, to a chamber for a gas lifting apparatus, which is used in a gas lifting apparatus for lifting a target by gas, In addition, the present invention relates to a chamber for a gas floatation apparatus which minimizes leakage of a laser used for processing an object to prevent the occurrence of a safety accident.
In the chamber for a gas lifting apparatus, a space is formed in which a target object can be inserted and lifted inward, a discharge hole for discharging the processed specimen in a lower portion thereof, And a lid part coupled to the upper part of the main body part to seal the chamber.

Description

{Chamber for an aerodynamic levitator}

The present invention relates to a chamber for a gas lifting apparatus, and more particularly, to a chamber for a gas lifting apparatus, which is used in a gas lifting apparatus for lifting a target by gas, In addition, the present invention relates to a chamber for a gas floatation apparatus which minimizes leakage of a laser used for processing an object to prevent the occurrence of a safety accident.

In general, levitation is a technique of floating an object in the air without a container for holding the object or a support for holding it. Recently, due to the development of technology, levitation has been used in industries such as magnetic levitation trains, mobile phones, semiconductor processes, Is used closely.

Various methods are used for levitation techniques developed up to now. Examples of methods for lifting a relatively bulky object include electromagnetic levitation, electrostatic levitation, acoustic levitation, aerodynamic levitation, Superconducting levitation methods using superconducting phenomena are being used, optical levitation methods for lifting atoms or molecules, quantum levitation techniques for lifting nano- or micro-sized materials, etc. Is being developed.

Among them, the aerial lift technique using air pressure, that is, the gas pressure, has the advantage of lifting almost all materials, but it is difficult to control the stability due to the rotation or shaking of the object when the float is lifted. .

As a prior art related to aerial lifting apparatus using air force, US Pat. No. 5,215,688 discloses a aerial lifting apparatus and method using aerodynamic force. The main technical configuration of the apparatus includes a profile generator, a flow of fluid The liquid droplet can be floated by using an air force.

However, the above-described structure is constructed so that only the liquid droplet can be lifted, and the problem of stability of the lifting is still included, which is not applicable to the floating of solid materials such as ceramics.

In addition, Korean Patent Publication No. 10-0253621 discloses a separator for separating polymer mixed pulverized material using air floating, and its main technical constitution is as shown in Fig. 1, in which two or more polymer mixed pulverized materials are fed A conveyor belt 1; An inlet 21 which is covered on the conveyor belt 1 and is disposed at one side of the conveyor belt 1 and into which the pulverized material is inputted; an outlet 22 disposed on the other side of the conveyor belt 1; , And a chamber (2) formed with an upper distributing mechanism (23); An air compressor 5 installed at a lower portion of the conveyor belt 1 to generate compressed air to levitate the pulverized material so as to form a layer by specific gravity; A first collecting bath (7) connected to the outlet (22) of the chamber (2); A plurality of diaphragms arranged vertically and horizontally in such a manner that only the crushed material having a small volume and a small specific gravity is passed through the chamber; (3) having a gradient shape in which the distance from the conveyor belt (1) decreases toward the outlet (22) from the inlet (21) to the conveyor belt (1). A vacuum pump 6 connected to the branching mechanism 23 of the chamber 2 to generate vacuum pressure for forcibly sucking the pulverized product having passed through the diaphragm body 3 by the branching mechanism 23; And a second collecting tank (8) connected to the vacuum pump (6).

That is, although the prior art includes the configuration of the chamber 2 used for air lifting, since it is desired to simply separate two or more kinds of polymer mixed pulverized materials by difference in specific gravity, There is a problem that it can not be used.

Therefore, as described above, the structure of the chamber which can stably float and process the solid material such as ceramics has not existed to date.

SUMMARY OF THE INVENTION The present invention has been conceived to solve the problems of the prior art as described above, and it is an object of the present invention to provide a method of manufacturing a ceramic test piece by non- And to provide a chamber for a gas floatation device.

In addition, the present invention provides a chamber for a gas flushing apparatus which can easily confirm the lifting and melting process of a target object, and can also safely and easily discharge the completed sample into the chamber. There is another purpose in.

According to an aspect of the present invention,

A chamber for a gas flushing apparatus, comprising: a space portion formed to allow a target object to be inserted and lifted inward; a discharge hole for discharging the processed specimen in a lower portion; and a gas- And a lid unit coupled to an upper portion of the main body to seal the chamber.

At this time, the main body is formed with a coupling hole formed to communicate with the gas introduction path and into which a nozzle for receiving an object is inserted.

In addition, an object dispensing device is provided at an upper portion of the lid to allow an object to be introduced into the chamber.

The object dispensing apparatus includes a fixed plate fixed to the lid unit, a loading disc coupled to the upper portion of the fixed plate, a slider connected between a lower portion of the fixed plate and the nozzle, And a motor for rotating the loading disk.

At this time, an upper surface of the fixing plate is provided with a mounting groove into which a mounting disk is inserted, and a coupling groove into which a shaft of the motor is inserted is formed at the center of the mounting groove. 1 through holes are formed.

In addition, a plurality of second through-holes are formed in the center of the stacking disk, and a plurality of second through-holes are formed in edge portions of the stacking disk to allow the object to pass therethrough.

The slider is provided with a guide groove for moving a target object, and a third through hole is formed at a lower end of the slider.

The apparatus may further include a specimen collection device installed at a lower portion of the main body to collect the specimen discharged through the discharge hole.

The specimen collecting apparatus includes a specimen collecting unit slidably coupled to a lower portion of the main body, and a crucible accommodating the specimen discharged through the specimen collecting shed.

An upper part of the lid part is provided with an optical device for transmitting a laser so as to heat the object held inside the main body part by laser.

The optical device includes a fixed frame coupled to the cover, a ZnSe lens coupled to the first coupling portion formed at the central portion of the fixed frame, and a ZnSe lens formed radially in the fixed frame around the first coupling portion A plurality of second joining portions, and a holder for fixing the ZnSe lens and the viewing window.

The fixed frame is formed with an inclined surface, and the second coupling portion is formed on the inclined surface so that the transparent window, which is coupled to the second coupling portion, is inclined toward the object so as to be symmetrical with respect to the ZnSe lens.

According to the present invention, it is possible to stably float a target by the pressure of a gas, thereby making it possible to manufacture a ceramic specimen in a noncontact manner without using a separate container, thereby preventing contamination It has an excellent effect that can be prevented.

In addition, according to the present invention, not only the lifting and melting process of an object can be visually confirmed easily, but also the effect of injecting the object into the chamber and discharging the completed specimen can be secured and facilitated.

1 is a cross-sectional view showing an internal structure of a separation apparatus for polymer mixed pulverized material using a conventional air float.
2 is a perspective view showing an outer appearance of a chamber for a gas flushing device according to the present invention;
3 is a side view showing an internal view of a chamber for gas floatation according to the present invention.
4 is a plan view of the present invention shown in Fig.
FIG. 5 is a plan view of the chamber body of the present invention shown in FIG. 2; FIG.
6 (a) and 6 (b) are a plan view and a side view, respectively, of a loading disk coupled to an upper portion of a fixed plate of the present invention shown in FIG.
7 (a) and 7 (b) are a front view and a left side view of the slider coupled to the lower portion of the fixed plate of the present invention shown in Fig. 2;
FIG. 8 is a cross-sectional view of the nozzle of the present invention shown in FIG. 3; FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

FIG. 2 is a perspective view showing an outer appearance of a chamber for a gas lifting apparatus according to the present invention, FIG. 3 is a side view showing an inner appearance of a chamber for gas lifting according to the present invention, FIG. 6 is a plan view of the chamber body of the present invention shown in FIG. 2, and FIGS. 6 (a) and 6 (b) 7 is a front view and a left side view showing a slider coupled to a lower portion of a fixed plate in the present invention shown in Fig. 2, and Fig. 8 is a plan view and a side view 1 is a cross-sectional view of a nozzle in the invention.

The present invention can be applied to a gas lifting device which can lift a target by gas so as to facilitate the input and discharge of the object inside the gas lifting device, The present invention relates to a chamber 10 for minimizing the occurrence of safety accidents and preventing the occurrence of safety accidents. The chamber 10 includes a main body 100 and a lid 200 as shown in Fig.

More specifically, the main body 100 serves to provide a space for allowing a target object to be inserted and processed. The main body 100 includes a space portion (not shown) And a discharge hole 120 is formed in the lower center of the lower portion so that the specimen produced by the machining of the object can be discharged.

3, the inner surface of the lower portion of the space 110 is formed to be inclined in a hemispherical shape so that the specimen produced by the laser processing of the object can be easily recovered through the discharge hole 120 Consists of.

A gas inlet path 130 is formed in the lower portion of the main body 100 so as to provide a gas used for lifting the object to the inside of the main body 100. The gas inlet path 130, Is formed to be spaced apart from the discharge hole 120 formed in the lower central portion of the space portion 110 and communicated with the coupling hole 140 into which the nozzle 170 described later is inserted, The gas supplied through the nozzle 170 flows into the inside of the main body 100 through the gas injection hole 172 formed in the nozzle 170 to float the target object placed on the nozzle 170.

That is, the nozzle 170 is installed inside the main body 100, that is, in the coupling hole 140, so that a target object for processing can be positioned thereon. Is conical for the object of the object.

A gas inlet hole 172 is formed at the center of the nozzle 170 so that the gas supplied through the gas inlet path 130 can be introduced into the main body 100, So that the gas supplied through the gas inlet path 130 can be discharged at a high speed through the gas inlet hole 172 so that the nozzle 170 The object accommodated in the air conditioner is configured to be supported in the air.

A flange 150 is formed on the lower portion of the main body 100 to fix the chamber 10 using bolts or the like. A slide groove 160 in which the recovery device 400 is slidably engaged is formed.

Next, the lid part 200 serves to seal the upper part of the main body part 100 so as to prevent contamination of other equipment used for processing the target object by blocking the evaporation gas generated during the processing of the target object And is composed of a flat plate.

At this time, the surfaces of the main body 100 and the lid 200 are anodized using an aluminum alloy material.

The lid part 200 is formed to protrude outward from the main body part 100 at one side end thereof. The lid part 200 is provided with a protruding part, A target object injection device 300 is provided.

More specifically, the object dispensing apparatus 300 includes a fixed plate 310, a loading disc 320, a slider 330, and a motor 340. The fixed plate 310 includes a target insertion device 2, the fixing plate 310 is provided on the upper surface thereof with a mounting groove 312 (see FIG. 2) in which the mounting disc 320 is inserted. A coupling groove 314 is formed at the center of the mounting groove 312 to receive a shaft of a motor 340 to be described later. An object is passed through the edge of the mounting groove 312, Hole 316 for allowing the slider 330 to be inserted into the slider 330 is formed to communicate with the slider 330 to be described later.

Next, the loading disc 320 is inserted into an installation groove 312 formed in the upper portion of the fixing plate 310 and the object is fixed to the main body 100 through the fixing plate 310 by driving the motor 340. [ And the motor 340 is inserted into the loading disc 320 and rotates the loading disc 320 to move the object on the loading disc 320 to the main body 100 To the inside of the main body.

6A and 6B, a coupling hole 322 is formed at the center of the loading disc 320 to fasten the motor 340, so that when the motor 340 rotates, When the loading disc 320 is rotated by driving the motor 340, the object on the loading disc 320 is driven to the edge of the loading disc 320 by the centrifugal force And then passes through a plurality of second through holes 324 formed in the edge portion of the stacking disk 320. The object that has passed through the second through hole 324 is again passed through the first And can be inserted into the main body 100 through the through holes 316.

3, the slider 330 is connected to a lower portion of the fixing plate 310 and a nozzle 170 installed inside the main body 100, so that the fixing plate 310 7A and 7B, the object to be supplied through the first through-hole 316 is moved to the upper portion of the nozzle 170, A third through hole 334 is formed in the lower end of the slider 330 and the object moved along the guide groove 332 is inserted into the third through hole 334, So that it can be seated on top of the nozzle 170.

Therefore, the object to be placed on the loading disc 320 can be automatically inserted into the second through hole 324, the first through hole 316, and the third through hole 334 by the object throwing apparatus 300 configured as described above. The ink can be injected onto the nozzle 170 through the nozzle.

3, the specimen collection apparatus 400 is detachably installed in the slide groove 160 formed in the lower portion of the main body 100. The specimen collection apparatus 400 includes a main body 100 To recover the processed specimen discharged through the discharge hole 120 of the wafer W.

The specimen collection device 400 includes a specimen collection port 410 and a crucible 420. The specimen collection port 410 is connected to the slide groove 160 of the body 100, And the crucible 420 is inserted into the fixing groove 412 formed on the specimen collection port 410 so as to be positioned below the discharge hole 120 of the main body 100, Thereby allowing the sample to be dropped through the discharge hole 120 to be received.

At this time, the specimen collection port 410 is provided with a handle 414 protruding outward of the body 100 to facilitate sliding of the specimen collection port 410.

Therefore, the use of the sample recovery apparatus 400 has an advantage that the processed high-temperature specimen can be safely recovered without opening the lid 200 of the chamber 10.

An upper part of the lid part 200 corresponding to the upper part of the lid part 200, that is, the lid part 200 corresponding to the main body part 100, is provided with an optical device The optical device 500 includes a fixed frame 510, a ZnSe lens 520, a viewing window 530, and a holder 540, as shown in FIGS.

More specifically, the fixed frame 510 includes a ZnSe lens 520 for allowing a laser to be transmitted to a target object to be transmitted, and a viewing window 530 for observing the lifting and processing of an object with the naked eye, And a first engaging portion 512 for engaging the ZnSe lens 520 is formed at the center of the fixed frame 510, A plurality of second engaging portions 514 for engaging the viewing window 530 are formed radially around the first engaging portions 512 on the outer side of the first engaging portions 512.

At this time, the first coupler 512 is connected to the nozzle 170 through the ZnSe lens 520 to allow the laser, which is transmitted to the inside of the chamber 10, to accurately heat the object in the floating state on the nozzle 170 The second engaging portion 514 is formed so as to be positioned vertically above the main body 100. The second engaging portion 514 is formed so as to be positioned vertically above the main body 100 through the sight window 530, On the inclined surface 516 of the fixed frame 510 which is formed so as to incline toward the center of the fixed frame 510.

Next, the ZnSe lens 520 is fastened to the first coupling part 512 formed at the center of the fixed frame 510 so that a laser generated by a laser generator, more specifically, a CO2 laser (not shown) The multilayer antireflection film coating layer is formed on both sides of the ZnSe lens 520. The multilayer antireflection film coating layer is formed on both sides of the ZnSe lens 520. [

That is, unlike a general lens, the ZnSe lens 520 penetrates the inside of the main body 100 without reflecting the laser, thereby preventing accidents caused by diffuse reflection and improving the accuracy of object processing , Ge, Si, or the like, a part of the visible light is transmitted, thereby facilitating the adjustment of the optical axis of the laser.

The viewing window 530 is fastened to the second engaging portion 514 formed on the inclined surface 516 of the fixed frame 510 and is provided symmetrically about the ZnSe lens 520, (Not shown) such as a camera and an infrared radiation thermometer (not shown) for measuring a temperature of a target object while observing the lifting and melting process of an object generated inside the main body 100 by using a photographing equipment And the like.

In addition, the viewing window 530 is manufactured using a quarz lens having high transmittance with respect to light having an infrared wavelength so that reliability of measurement data can be improved during temperature measurement using an infrared radiation thermometer during processing of an object .

The holder 540 allows the ZnSe lens 520 and the see-through window 530 to be more firmly fixed on the fixed frame 510. The holder 540 is used for fixing the ZnSe lens 520 A first holder 540a and a second holder 540b for fixing the viewing window 530. [

At this time, a groove (not shown) is formed in the first and second holders 540a and 540b to receive a ZnSe lens 520 or a see-through window 530. At this time, It is preferable to prevent the ZnSe lens 520 or the viewing window 530 from being damaged due to thermal expansion due to a temperature increase inside the chamber 10 by making it deeper than the thickness of the viewing window 530. [

Therefore, according to the chamber 10 for a gas lifting apparatus according to the present invention constructed as described above, it is possible to stably float a target by the pressure of a gas, thereby manufacturing a ceramic specimen in a noncontact manner without a separate container So that contamination due to the use of the container can be prevented during manufacture of the specimen using the object, and the lifting and melting process of the object can be easily confirmed with the naked eye. In addition, the introduction and completion of the object into the chamber 10 It is possible to securely and easily discharge the specimen.

Although the preferred embodiments of the present invention have been described for illustrative purposes, those skilled in the art will readily appreciate that many modifications are possible in the exemplary embodiments without materially departing from the novel teachings and advantages of this invention.

The present invention relates to a chamber for a gas lifting apparatus, and more particularly, to a chamber for a gas lifting apparatus, which is used in a gas lifting apparatus for lifting a target by gas, In addition, the present invention relates to a chamber for a gas floatation apparatus which minimizes leakage of a laser used for processing an object to prevent the occurrence of a safety accident.

10: chamber 100:
110: Space part 120: Exhaust hole
130: gas inlet line 140: coupling hole
150: flange 160: slide groove
170: nozzle 172: gas injection hole
200: lid part 300: object input device
310: Fixing plate 312: Installation groove
314: coupling groove 316: first through hole
320: loading disc 322: fastening hole
324: second through hole 330: slider
332: guide groove 334: third through hole
340: motor 400: specimen collection device
410: Specimen collection port 412: Fixing groove
414: Handle 420: Crucible
500: optical device 510: fixed frame
512: first coupling portion 514: second coupling portion
516: sloped surface 520: ZnSe lens
530: view window 540: holder
540a: first holder 540b: second holder

Claims (12)

A chamber for a gas flushing device,
A body portion formed with a space for allowing the object to be inserted and floated inside, a discharge hole for discharging the processed specimen and a gas inlet for supplying the gas to the space,
And a lid part coupled to an upper part of the main body part to seal the chamber,
The body is formed with a coupling hole communicating with a gas introduction path, and a nozzle accommodating an object is inserted into the coupling hole, the object is floated by the gas injected from the nozzle,
And an object dispensing device for dispensing an object to the inside of the chamber is provided at an upper portion of the lid,
The object dispensing apparatus includes a fixed plate fixed to the lid unit, a loading disc coupled to the upper portion of the fixed plate, a slider connected between a lower portion of the fixed plate and the nozzle, And a motor for rotating the disk.
delete delete delete The method according to claim 1,
Wherein a mounting groove is formed in the upper surface of the fixing plate so that a loading disc is inserted into the mounting groove, a coupling groove into which a shaft of the motor is inserted is formed in the center of the mounting groove, And a hole is formed in the chamber.
The method according to claim 1,
And a plurality of second through holes through which the object passes are formed in the edge portion of the loading disc, wherein a coupling hole for fastening the motor is formed at the center of the loading disc.
The method according to claim 1,
Wherein the slider is provided with a guide groove for moving an object, and a third through hole is formed at a lower end of the slider.
The method according to claim 1,
Further comprising a specimen collection device installed at a lower portion of the main body to collect the specimen discharged through the discharge hole.
9. The method of claim 8,
Wherein the specimen collection device includes a specimen collection port slidably fitted to a lower portion of the body portion and a crucible accommodated in the specimen collection port and accommodating a specimen discharged through the vent hole. chamber.
The method according to claim 1,
Wherein an upper surface of the lid is provided with an optical device for transmitting a laser so as to heat an object contained in the main body by a laser.
11. The method of claim 10,
The optical device includes a fixed frame coupled to the cover, a ZnSe lens coupled to the first coupling portion formed at the center of the fixed frame, and a plurality of And a holder for fixing the ZnSe lens and the viewing window to each other.
12. The method of claim 11,
Wherein the fixed frame is formed with an inclined surface and the second coupling portion is formed on an inclined surface so that a transparent window to be coupled to the second coupling portion is inclined toward the object so as to be symmetrical with respect to the ZnSe lens. .

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