KR20200008800A - Integrated 2-stage ejector - Google Patents

Abstract

An integrated two-stage ejector is disclosed. According to the present invention, the integrated two-stage ejector may comprise: a first nozzle unit for generating negative pressure by passing a gas supplied at a pressurized pressure through a nozzle; a second nozzle unit having a nozzle having an opening or narrowing size enlarged compared to that of a nozzle of the first nozzle unit in order to form a differential pressure with the first nozzle unit to suck the gas so that a relatively small negative pressure is formed compared to a negative pressure formed by a gas flow rate; an inhaler installed to surround the outside of the second nozzle unit to induce external fluid suction through the gas sucked into the second nozzle unit; and a diffuser extending from the inhaler to discharge the input gas and the sucked fluid.

Description

Integrated 2-stage ejector

The present invention relates to an integrated two-stage ejector that increases the discharge flow rate to supply pressure of the fluid without a separate power supply.

Ejectors are used to transfer fluids. Existing ejectors are divided into small capacity and large capacity. If the input flow rate is larger than the set flow rate, the ejector cannot be used for reasons such as reverse flow, and the large capacity ejector may not be used for the reason that the discharge flow rate is less than the set flow rate. Therefore, the ejector had to be used separately according to the input flow rate, and the ejector may not be used if a sudden change in the input flow rate is required. In addition, when the fluid is recovered and discharged, a low recovery efficiency may require a large number of ejector combination structures to secure a desired recovery flow rate.

Patent Documents 1. Korean Patent Publication No. 10-2013-0131523 (published December 4, 2013)

Patent Document 2. Domestic Publication No. 10-2010-0048892 (published May 11, 2010)

One of the technical problems to be solved by the present invention is to increase the discharge flow rate to the gas supply pressure without a separate power supply.

According to the present invention, the first nozzle unit for generating a negative pressure by passing the gas supplied at a pressurized pressure through the nozzle; The nozzle is formed to have a differential pressure and the size of the gap is narrow or narrow compared to the negative pressure formed by the flow rate of the gas to form a differential pressure with the first nozzle portion is expanded compared with the nozzle of the first nozzle portion A second nozzle unit; An inhaler disposed to surround the outside of the second nozzle unit to induce the intake of external fluid through the gas sucked into the second nozzle unit; And a diffuser extending from the inhaler to stabilize and discharge the input gas, the fluid pressure and the air flow sucked in from the inhaler.

According to an embodiment of the present invention, the second nozzle part has an expansion part for inducing the entry of the nozzle end of the first nozzle part, and the expansion part has at least one suction hole to suck the external fluid through the differential pressure. Can be configured.

According to an embodiment of the present invention, the inhaler may be configured to surround the second nozzle unit in a spaced apart state, and have a flow space for suction flow of the external fluid, thereby introducing the external fluid to suck the external fluid through the differential pressure.

According to an embodiment of the present invention, the inhaler may include at least one suction port for sucking external fluid.

According to an embodiment of the present invention, the diffuser is composed of an asymmetrical expansion portion extending from the inhaler, and the flow path is narrower and farther away from the second nozzle in order to stabilize and discharge the input gas, the fluid pressure and the airflow to be sucked out. The termination may have a flange that can be assembled to the mating structure.

The present invention has the effect of increasing the discharge flow rate because it can suck out the external fluid at the gas supply pressure without a separate power supply.

In addition, the two-stage ejector is integrated to improve the gas ejection and backflow problems of the existing ejector, and it is possible to change the ejector according to the input flow rate. There is.

In addition, there is an effect that can be usefully applied to recover and reuse the waste fluid discarded in the heat treatment furnace.

1 is an illustration of an integrated two-stage ejector according to an embodiment of the present invention.
2 is an illustration showing a fluid flow flow of the input gas and the suction gas in the integrated two-stage ejector according to an embodiment of the present invention.
3 is an illustration showing an application example of the present invention in a heat treatment furnace.

Hereinafter, with reference to the accompanying drawings will be described in detail the 'integrated two-stage ejector' according to a preferred embodiment of the present invention.

The integrated two-stage ejector according to the embodiment of the present invention sucks and discharges the surrounding fluid with the vacuum pressure of the fluid passing through the first and second nozzle parts, and suctions the surrounding fluid with the vacuum pressure to the discharged fluid once more to recover the recovery rate. It is suggested to increase.

In addition, the two-stage ejector is manufactured in one piece to improve the structure that backflow or injection was impossible, and it is proposed to be used without changing according to the input flow rate with only one two-stage ejector in the existing method used by changing the ejector according to the input flow rate. .

1 is an illustration of an integrated two-stage ejector according to an embodiment of the present invention. The integrated two-stage ejector according to the present invention may be configured as a first nozzle unit 100 for generating a negative pressure by passing the gas supplied at a pressurized pressure through the nozzle 110 as shown in FIG. The nozzle 110 may be formed at one end of the first nozzle unit 100. The nozzle 110 is formed to be narrower or gradually smaller in size than the supply port 120 to which the input gas is supplied so as to generate a negative pressure.

In addition, the first nozzle unit is formed to have a gap or narrow size to form a differential pressure with the first nozzle unit 100 so as to form a sound pressure relatively smaller than the sound pressure formed by the flow rate of the input gas Gf to suck the external fluid. It may be composed of a second nozzle unit 200 having a nozzle 210 extended compared to the nozzle 110 of (100).

The second nozzle unit 200 may include an expansion unit 220 for inducing entry of an end portion of the nozzle 110 of the first nozzle unit 100. The expansion tube 220 may be configured to include at least one suction hole 230 to introduce suction gas Ef, which is an external fluid, through the suction hole 230.

In addition, the inhaler 300 may be installed to surround the outside of the second nozzle unit 200 to induce the intake of external fluid through the gas sucked into the second nozzle unit 200.

The inhaler 300 may be configured to include a flow space 320 that surrounds the second nozzle unit 200 in a spaced apart state and suction flows external fluid. In addition, the inhaler 300 may be configured to include at least one or more inlet port 330 for sucking external fluid and a fluid inlet 310 extending from the inlet port 330 to stably induce the intake of the fluid.

In addition, it may be configured as a diffuser 400 extending from the inhaler 300 to stabilize and discharge the input gas, the fluid pressure and the air flow sucked in.

The diffuser 400 extends from the inhaler 300 to asymmetrically expand the passage width toward the second nozzle 200 in order to stabilize and discharge the input gas, the fluid pressure and the airflow which are inflated, and the width of the passage becomes wider. Consists of the tube 410, the end may be configured with a flange 420 that can be assembled to the mating structure.

2 is an illustration showing a fluid flow flow of the input gas and the suction gas in the integrated two-stage ejector according to an embodiment of the present invention.

The integrated two-stage ejector according to the embodiment of the present invention sucks the surrounding fluid by the vacuum pressure of the fluid (inlet gas) passing through the nozzles 110 and 210 of the first and second nozzle units 100 and 200. The suction and discharge of the surrounding fluid by vacuum pressure to the discharged and discharged fluid once again acts to increase the recovery flow rate of the suction gas as a whole.

As shown in FIG. 2, when the unitary two-stage ejector according to the present invention injects the input gas Gf at a pressure through the first nozzle part 100, the input gas Gf is formed in the direction of the arrow F1 in the first nozzle part ( The negative pressure may be generated while passing through the nozzle 110 along the supply port 120 of the 100.

The input gas Gf passing through the nozzle 110 of the first nozzle part 100 is arrowed through the inlet hole 230 through the suction gas Ef, which is an external fluid, due to the pressure difference in the second nozzle part 200. It can be inhaled in the F2 direction.

At this time, the suction gas Ef corresponding to the flow rate of the suctioned gas is sucked in the direction of arrow F3 through the fluid inlet 310 and the inlet 330 of the inhaler 300 to increase the flow rate of the flow space 320. Let's go.

When the differential pressure is generated in the second nozzle unit 200 by the pressure of the input gas Gf introduced from the first nozzle unit 100, the external suction gas Ef may be sucked through the inhaler 300. The flow rate of the gas exiting or exiting the diffuser 400 in the direction of arrow F4 may be increased.

If the suction gas (Ef) is a gas that needs to be recovered, it is possible to finally increase the recovery amount of the gas.

The present invention can be applied as a preferred ejector in the field of recovering and recycling the waste gas. 3 is an illustration showing an application example of the present invention applied to a heat treatment furnace.

As shown in FIG. 3, the heat treatment furnace 500 includes a cabinet 510 and a chamber 510 including a chamber 520, which is a space for accommodating and heat-treating a workpiece (for example, an LCD glass substrate as a heat treatment target). 520 is configured to communicate with the inlet 530 for injecting a gas such as nitrogen (N ₂ ) into the chamber 520, and the remaining waste heat and nitrogen in the chamber 520 that are configured to communicate with the chamber 520. And an exhaust port 540 for exhausting a gas such as N ₂ ).

An exhaust flow path 550 is provided in the exhaust port 540, and a recovery induction flow path 560 for recovering the exhaust fluid flowing along the exhaust flow path 550 is provided and the integrated two-stage of the present invention is provided. The injector 300 of the ejector is connected to the recovery induction flow path 560 to recover the nitrogen (N ₂ ) gas and the waste heat air that are discarded along the exhaust flow path 550 into the chamber 520 through the intake and intake ports 530. By using it can be recycled while increasing the recovery rate of nitrogen gas and waste heat discarded when applied to the heat treatment furnace 500 has an advantage that can be particularly useful in heat treatment furnaces.

Although the present invention has been described with reference to the embodiments illustrated in the drawings, the present invention is not limited to the embodiments and may be modified and modified without departing from the spirit of the present invention, and modifications and variations are included in the technical idea of the present invention. do.

100: first nozzle unit 110: nozzle
200: second nozzle portion 210: nozzle
220: expansion pipe 230: inflow hole
300: second nozzle portion 310: fluid inlet
320: flow space 330: inlet
400: diffuser

Claims (5)

A first nozzle unit configured to generate a negative pressure by passing a gas supplied at a pressurized pressure through the nozzle;
A nozzle having a size that is spaced or narrowed to form a differential pressure with the first nozzle portion so as to form a sound pressure relatively smaller than the sound pressure formed by the flow rate of the gas so as to suck the gas to expand the nozzle compared with the nozzle of the first nozzle portion. A second nozzle unit provided;
An inhaler disposed to surround the outside of the second nozzle unit to induce the intake of external fluid through the gas sucked into the second nozzle unit; And
And a diffuser extending from the inhaler and discharging the injected gas and the sucked fluid. The method of claim 1,
And the second nozzle portion has an expansion pipe portion for inducing entry of the nozzle end of the first nozzle portion, and the expansion pipe portion has at least one suction hole. The method of claim 1,
And said inhaler encloses said second nozzle portion spaced apart and has a flow space for suction flow of external fluid. The method of claim 3, wherein
And the inhaler has at least one intake port for inhaling external fluid. The method of claim 1,
The diffuser is composed of an asymmetrical expansion portion extending from the inhaler, the flow path is closer to the second nozzle and narrower and farther away from the inlet gas and the fluid pressure and air flow to be discharged, and the passage area is expanded. An integrated two-stage ejector with a flange that can be assembled to the.

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