KR20030086716A - Air ejector of a apparatus for generating a vaccum - Google Patents

Abstract

PURPOSE: An air ejector of a vacuum generator is provided to improve vacuum efficiency of a vacuum chamber in a high temperature atmosphere by easily sucking high-temperature fluid from the vacuum chamber. CONSTITUTION: An air ejector includes an ejector body(10) and a plurality of annular nozzle members(20). The ejector body(10) sucks and discharges fluid contained in a vacuum chamber(30). The annular nozzle members(20) are arranged at an outer surface of the ejector body(10) so as to generate negative force in the ejector body(10). The ejector body(10) has a pipe shape. The ejector body(10) is formed at a downstream part thereof with a suction port(10a), to which a suction pipe(40) of the vacuum chamber(30) is coupled. A discharge port is formed at an upstream part of the ejector body(10) so as to discharge fluid to an exterior.

Description

Air ejector of a apparatus for generating a vaccum

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vacuum generating device, and more particularly, to generate a vacuum to more easily inhale and discharge a high temperature gas in a vacuum chamber in a high temperature atmosphere such as an electric furnace to further improve vacuum efficiency in the vacuum chamber in a high temperature atmosphere. It relates to an air ejector.

In general, the vacuum generating device is an apparatus for achieving an efficient vacuum degree in the vacuum chamber required in the chemical, food, steelmaking, semiconductor field, and various industrial fields.

Such a vacuum generator device is basically a vacuum pump device in which a vacuum pump is connected through a suction pipe to a vacuum chamber for achieving vacuumization, thereby achieving a degree of vacuum in the vacuum chamber by the suction action of such a vacuum pump, and such a vacuum pump device As an alternative to this, there has been an air ejector apparatus which injects a high pressure gas to the nozzle side to generate a negative pressure, thereby sucking the fluid in the vacuum chamber and evacuating the inside of the vacuum chamber.

The air ejector used in the air ejector device is formed in a tubular shape and extends in the longitudinal direction, the nozzle is formed on the axis of the ejector body and the compressed air supplied from the compressed air source is injected at a high speed and And a negative pressure chamber formed near such a nozzle to form a negative pressure by high-speed compressed air injected into the nozzle, and a suction pipe formed on an outer circumferential surface of the negative pressure chamber side of the ejector body and extending from the vacuum chamber to the nozzle of the negative pressure chamber. And an intake port coupled at right angles to the axis, and an outlet port formed at an upstream end of the nozzle to discharge sucked fluid and compressed air to the outside.

When such a high-speed compressed air is injected into the nozzle from the compressed air source, the air ejector generates negative pressure in the negative pressure chamber formed near the nozzle. Due to this negative pressure, the fluid in the vacuum chamber is sucked through the suction pipe extending from the vacuum chamber and discharged to the outside through the discharge port together with the compressed air.

However, in the conventional axial air ejector, when the hot fluid in the vacuum chamber of a high temperature atmosphere such as an electric furnace is sucked in, the nozzle tip is exposed to the hot fluid sucked in a direction perpendicular to the nozzle. Or to be damaged.

In addition, in the case of a vacuum generator using a conventional vacuum pump, there is a problem that the vacuum pump has a lot of temperature constraints due to the limitation of the impeller and various packing materials therein.

The present invention has been devised in view of the above, and easily inhales high temperature fluid in a vacuum chamber of a high temperature atmosphere such as an electric furnace to further improve the vacuum efficiency inside the high temperature atmosphere vacuum chamber and is free from temperature constraints. The purpose is to provide an air ejector.

1 is a partial cutaway perspective view showing an air ejector according to an embodiment of the present invention.

Figure 2 is a cross-sectional view of the air ejection in accordance with an embodiment of the present invention.

2 is a use state diagram showing a state in which the air ejector of the present invention is applied to a vacuum generating device.

Explanation of symbols on the main parts of the drawings

10 ejector body 20 annular nozzle body

30 vacuum chamber 40 suction tube

50: compressed air source

The present invention for achieving the above object is made of a tubular shape, the ejector body having a suction port connected to the suction pipe extending from the vacuum chamber at the upstream end and a diffuser-shaped outlet formed on the downstream end; At least one supply is formed extending in the circumferential direction on the outer circumferential surface of the ejector body, formed in an annular shape having a hollow portion therein, and penetrated outwardly from the inside of the hollow portion to supply compressed air to the hollow portion from the compressed air source. It includes a plurality of annular nozzle body having a ball and having a nozzle portion formed inclined at a predetermined angle to communicate the hollow portion and the inside of the ejector body to inject the compressed air introduced into the hollow portion into the ejector body.

Preferably, a plurality of annular nozzle bodies are spaced apart by a predetermined interval in the longitudinal direction on the outer circumferential surface of the ejector body.

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

1 and 2 show an air ejector according to an embodiment of the present invention.

As shown, the air ejector of the present invention is formed on the ejector body 10 for sucking and discharging fluid in the vacuum chamber 30 therein, and formed on the outer surface of the ejector body 10 so as to form the ejector body ( And a plurality of annular nozzle bodies 20 for generating underpressure in the interior of 10).

The ejector body 10 has a conventional tubular shape having an outer diameter and an inner diameter. The ejector body 10 has a suction port 10a to which a suction pipe 40 extending from a vacuum chamber 30 to be described later is coupled to a downstream end thereof, and suctions from the vacuum chamber 30 at an upstream end thereof. A discharge port 10b for discharging a fluid to the outside is provided. The inlet 10a of the ejector body 10 has a shape in which the cross-sectional area increases from the suction pipe 40 toward the ejector body 10, and the outlet 10b of the ejector body 10 extends outside from the ejector body 10. Toward the cross-sectional area.

The annular nozzle body 20 is formed in an annular shape having a hollow portion 20a therein. The hollow portion 20a of the annular nozzle body 20 includes a nozzle portion 20b at a portion in contact with the inner side surface of the ejector body 10. The nozzle portion 20b is opened toward the inner surface of the ejector body 10 while being inclined at a predetermined angle. On the other hand, on the outer circumferential surface of the annular nozzle body 20, at least one supply hole 20c through which compressed air is supplied from the compressed air supply source 50 described later is formed. Meanwhile, the plurality of annular nozzle bodies 20 are spaced apart at predetermined intervals on the outer circumferential surface of the ejector body 10.

The use state, the effect, and the effect which the air ejector of this invention comprised as mentioned above is applied to the vacuum generating apparatus of a vacuum chamber are demonstrated in detail based on FIG.

A suction pipe 40 extending from the vacuum chamber 30 requiring a predetermined degree of vacuum is coupled to the suction port 10a of the ejector body 10, and the annular nozzle body 20 is formed on the outer surface of the ejector body 10. It is formed in the circumferential direction, and a plurality of such annular nozzle bodies 20 are spaced apart at predetermined intervals according to the desired vacuum efficiency. A compressed air supply source 50 such as a compressed air storage tank or a compressor is provided on the supply hole 20c side so that the compressed air is supplied to the supply hole 20c formed at one side of the annular nozzle body 20. Is connected through. On the other hand, on the supply pipe (50a) of the compressed air source 50, the adjusting means 60, such as an orifice and a regulator (regulator) for controlling the flow rate and pressure of the supplied compressed air may be installed.

First, compressed air is supplied from the compressed air supply source 50 to the hollow portion 20a of the plurality of annular nozzle bodies 20, and the compressed air in the hollow portion 20a is ejected at high speed through the nozzle portion 20b. Is sprayed onto the inner side of the. Accordingly, negative pressure is generated on the inner surface of the ejector main body near the nozzle part 20b, and the fluid in the vacuum chamber 30 is discharged by the negative pressure generated near the nozzle part 20b through the suction pipe 40. Suction into the inner surface of the The fluid in the vacuum chamber 30 sucked by the negative pressure is properly mixed with the compressed air at the outlet port 10b side of the ejector body 10 and is discharged while maintaining a constant pressure. When the above-described annular nozzle body 20 is disposed on the outer circumferential surface of the ejector body 10 at a predetermined interval, the compressed gas is sprayed in multiple stages to repeatedly perform the above-described suction action, so that the vacuum chamber 30 is more efficiently. It is characterized by achieving a degree of vacuum.

At this time, when the vacuum chamber 30 is a vacuum chamber of a high temperature atmosphere such as an electric furnace, when the hot gas in the vacuum chamber 30 is sucked into the inner surface of the ejector body 10, as described above, the annular nozzle Since the nozzle portion 20b of the sieve 20 is not exposed to the hot gas to be sucked, there is a feature that can be safely used even at high temperatures.

The present invention as described above, the high temperature fluid in the vacuum chamber of a high temperature atmosphere such as an electric furnace can be easily sucked to further improve the vacuum efficiency inside the high temperature atmosphere vacuum chamber, there is a very excellent effect free from temperature constraints.

In the above, the present invention has been illustrated and described with respect to certain preferred embodiments. However, the present invention is not limited only to the above-described embodiments, and those skilled in the art to which the present invention pertains may vary without departing from the spirit of the technical idea of the present invention described in the claims below. It may be changed.

Claims (2)

It relates to an air ejector of a vacuum generator for achieving an efficient degree of vacuum of the vacuum chamber, An ejector body having a tubular shape and having an intake port connected to a suction pipe extending from the vacuum chamber at an upstream end thereof and a diffuser shape outlet formed at a downstream end thereof; It is formed extending in the circumferential direction on the outer circumferential surface of the ejector body, and formed in an annular shape having a hollow portion therein, and is formed by penetrating outward from the inside of the hollow portion so that compressed air is supplied from the compressed air source to the inner hollow portion An annular nozzle having at least one supply hole and having a nozzle portion inclined at a predetermined angle so as to communicate the inside of the hollow part and the ejector body to eject the compressed air introduced into the hollow part into the inside of the ejector body Air ejector comprising a sieve. The air ejector according to claim 1, wherein a plurality of the annular nozzle bodies are disposed on the outer circumferential surface of the ejector main body and spaced apart at predetermined intervals in a longitudinal direction thereof.