KR20160037699A - Emissions quantity adjustable air blower unit - Google Patents

Abstract

The present invention relates to an air blower unit controlling emission quantity. The present invention includes: an inflow pipe taking in gas; a discharge pipe discharging the gas flowing in through the inflow pipe; a combination unit connecting the inflow pipe with the discharge pipe, forming a supercharging space part between the inflow pipe and the discharge pipe, and combining one end of the discharge pipe with the other end of the inflow pipe in order to form a supercharging hole connecting the supercharging space part to a discharge space part; and a control unit controlling the quantity of circulative gas, discharged to the discharge space part through the supercharging hole, by controlling the size of the supercharging space part. According to the present invention, the supercharged circulative gas causes a pressure difference to take in the gas through the inflow gas and quickly discharge the gas through the discharge pipe, and a blast volume is controlled through the inflow pipe and the discharge pipe by controlling the supercharging quantity of the circulative gas, and therefore, compatibility and working efficiency are improved.

Description

[0001] The present invention relates to an air blower unit,

The present invention relates to an air blower unit, and more particularly, to an air blower unit capable of blowing a gas by supercharging a circulating gas, adjusting a supercharge amount of the circulating gas to quickly blow gas, Of course, the present invention relates to an emission controllable air blower unit capable of improving working efficiency.

Generally, the air blast is blown to blow the outside gas into the inside or blow out the inside gas to the outside.

Such an air blur is caused by rotating the fan to blow air, and there is a problem in safety that a high temperature is generated in the motor and sparks are generated in a long-term use.

Thus, as disclosed in Registration Utility Model No. 20-0172668, the intake and exhaust device has a trumpet-type exhaust hole formed from a curved surface at the left end, and a cylindrical body having a threaded portion at the intermediate outer periphery and a cylindrical outer body having a left- Compressed air is ejected in the direction of the arrow and the pneumatic compartment and is sucked and exhausted by the ejection phenomenon.

However, this suction / exhaust device is designed such that the air outlet port of the pneumatic chamber is positioned in the direction of the intake pipe as compared with the portion where the compressed air is supplied to the pneumatic chamber, and the direction of the compressed air is ejected into the intake pipe rather than the discharge hole of the cylindrical body, There is a problem that the back pressure is generated due to interference.

Particularly, the intake tube is fixed to the circular cylinder by using a fixing nut. The air cylinder is unstable due to the pressure of the compressed air or the shock which is transmitted from the outside, resulting in irregular circulation amount.

In order to solve this problem, the intake tube, the fixing nut and the cylindrical body are sealed and fixed by welding or the like. However, during operation, the pressure can not be controlled due to the condition, There was an inconvenience in that it had to be replaced and replaced with a suction / exhaust device.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a vacuum cleaner having a supercharging space, And a control means for controlling the amount of the circulating gas discharged to the discharge space portion through the supercharging ball by adjusting the space size of the supercharging space portion, The air blower unit is capable of controlling the amount of air blown through the inflow pipe and the discharge pipe by adjusting the supercharge amount of the purifying gas, thereby improving the working efficiency as well as the compatibility with the air blower unit The purpose is to provide.

According to an aspect of the present invention, there is provided an exhaust gas purifying apparatus including an inlet pipe having an inlet space therein, an inlet pipe for introducing gas, a discharge space communicating with the inlet space, a discharge pipe for discharging gas introduced into the inlet pipe, The other end of the inflow pipe is spaced apart from the one end of the discharge pipe by a predetermined distance so as to form a charge space between the inflow pipe and the discharge pipe and to form a charge hole communicating the charge space with the discharge space part, And adjusting means for controlling the amount of the circulating gas discharged to the discharge space portion through the supercharging ball by adjusting the space size of the supercharging space portion. When the circulating gas is supplied to the supercharging space portion, Pressure is generated as it is discharged to the discharge space part through the supercharger so that the gas can flow into the inflow space part of the inflow pipe Is being discharged with the gas supply cycle, which regulates the emission by controlling the discharge amount of the circulating gas by the control means is introduced into the inlet pipe to set up a gas emissions discharged into the discharge pipe.

Preferably, the inflow space portion of the inflow tube includes an inflow narrowing portion having the smallest cross-sectional area, a first inflow space portion whose surface is inclined so that the cross-sectional area gradually increases toward the one end with reference to the inflow narrowing portion, Wherein the inlet narrow portion is located so as to be closer to the other end than the one end, and the surface inclination of the second inlet space portion is smaller than that of the second inlet portion, 1 < / RTI > inlet space.

The discharge space of the discharge pipe has a discharge narrowing part having the smallest sectional area, a first discharge space part formed in a streamlined shape with a gradually increasing sectional area toward the one end with reference to the discharge narrowing part, And a second discharge space portion whose surface is inclined so that the cross-sectional area gradually increases toward the other end.

In addition, the sectional area of the discharge narrow portion is formed to be smaller than the sectional area of the inlet narrow portion.

The coupling means may include an inlet coupling block protruding along the outer circumferential surface of the inlet pipe, an inlet thread formed along an outer circumferential surface of the inlet coupling block, an outer circumferential wall surrounding the inlet coupling block, And a discharge thread formed along the inner circumferential surface of the discharge coupling tube so as to correspond to the inflow thread.

Further, the discharge coupling pipe is provided with a supercharging supply hole for supplying a circulating gas to the supercharging space, and the cross-sectional area of the supercharging space is gradually increased from one end of the supercharging supply hole to the opposite end of the inflow pipe, And is formed to gradually decrease.

The adjusting means includes a tube disposed in the supercharging space and a pump for controlling the size of the supercharging space according to expansion or contraction of the tube by adjusting the inner pressure of the tube.

The control means may include a control block positioned in the boost space, a plurality of control holes formed in the inlet coupling block and having threads formed along the inner circumferential surface thereof, an adjustment bolt coupled to the control hole, And an adjusting spring for connecting the adjusting bolt with the adjusting bolt in a direction of the adjusting bolt. When the adjusting bolt is moved in the direction of the overloading space of the boosting space part, When the adjustment bolt is moved in the direction opposite to the supercharging ball, the size of the supercharging space is increased by moving the adjusting block, and the adjusting block is brought into close contact with the adjusting bolt in the direction of the adjusting bolt .

Further, a guide part is further provided in any one of the inflow space and the discharge space part, and the guide part is fixed to the inflow pipe or the discharge pipe by a plurality of equally spaced wings of a conical body.

Further, a fluororesin coating layer is formed on the inner surfaces of the inflow space, the discharge space, and the boost space.

Further, a heating unit for heating the air blower unit is further provided.

In addition, the heating unit is provided in the adjusting means.

The heating unit is provided along the outer circumference of the inflow pipe and the discharge pipe.

As described above, according to the air-blower unit of the present invention, the pressure difference is generated by the circulating gas to be supercharged, the gas is introduced through the inflow pipe and is quickly discharged to the discharge pipe, and the supercharge amount of the purifying gas is controlled So that the amount of blowing air can be adjusted through the inflow pipe and the discharge pipe, which is a very useful and effective invention that can improve not only the compatibility but also the working efficiency.

1 is a view showing an air blower unit according to the present invention,
2 is a view showing the use state of the air blower unit according to the present invention,
3 is a view showing a distribution of gas flow by the air blower unit according to the present invention,
4 is a view showing the pressure distribution by the air blower unit according to the present invention,
Figure 5 is a view showing a coupling means according to the present invention,
6 is a view showing another embodiment of the boost space unit according to the present invention,
Figure 7 is a view showing the adjusting means according to the present invention,
8 is a view showing another embodiment of the adjusting means according to the present invention,
9 is a view showing a state in which a guide portion is further provided in the air blower unit according to the present invention,
10 is a view showing a state in which a heating unit is further provided in the air blower unit according to the present invention,
11 is a view showing another embodiment of the heating unit according to the present invention.

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

It should be noted that the present invention is not limited to the scope of the present invention but is only illustrative and various modifications are possible within the scope of the present invention.

FIG. 1 is a view showing an air blower unit according to the present invention, FIG. 2 is a view showing the use state of the air blower unit according to the present invention, and FIG. FIG. 4 is a view showing a pressure distribution by the air blower unit according to the present invention, FIG. 5 is a view showing a coupling means according to the present invention, and FIG. 6 is a cross- Fig. 7 is a view showing the adjusting means according to the present invention, Fig. 8 is a view showing another embodiment of the adjusting means according to the present invention, and Fig. 9 is a view showing another embodiment of the present invention FIG. 10 is a view showing a state in which a heating unit is further provided in the air blower unit according to the present invention, and FIG. 11 is a view showing a state in which the heating unit Fig.

As shown in the figure, the air-blower unit 10 capable of adjusting the emission amount is constituted of an inlet pipe 100 and a discharge pipe 200, a coupling means 300 and an adjustment means 400.

The inflow pipe 100 has an inflow space portion 110 therein and is provided to allow the inflow of gas.

The discharge tube 200 has a discharge space part 210 communicating with the inflow space part 110 and is provided for discharging the gas introduced into the inflow tube 100.

The coupling means 300 connects the inlet pipe 100 and the discharge pipe 200 and forms the boost space portion 302 between the inlet pipe 100 and the discharge pipe 200.

The other end of the inflow pipe 100 is spaced apart from the one end of the discharge pipe 200 by a predetermined distance so that a boosting hole 304 for communicating the boost space portion 302 to the discharge space portion 210 is formed.

The adjusting means 400 is provided to adjust the amount of the circulating gas discharged to the discharge space portion 210 through the supercharging hole 304 by adjusting the size of the space of the supercharging space portion 302.

As shown in FIGS. 2 to 4, when the circulating gas is supplied to the supercharging space 302, the discharge air is blown through the supercharging hole 304 The gas is introduced into the inflow space 110 of the inflow pipe 100 and is discharged together with the supplied circulating gas.

FIG. 3 shows the distribution of the air flow of the gas and the circulating gas by the air blower unit 10, and FIG. 4 shows the distribution of the pressure of the gas and the circulating gas by the air blower unit 10.

The control unit 400 controls the discharge amount of the circulating gas to adjust the discharge amount of the gas that flows into the inflow pipe 100 and is discharged to the discharge pipe 200 to be set.

The inflow space 110 of the inflow pipe 100 includes the inflow narrowing portion 112 and the first inflow space 114 and the second inflow space 116. [

The inlet narrowing portion 112 has the smallest cross-sectional area, and the first inlet space 114 is inclined with respect to the inlet narrowing portion 112 such that the cross-sectional area gradually increases toward one end.

The second inflow space portion 116 is inclined with respect to the inflow narrowing portion 112 so that the cross-sectional area gradually increases toward the other end.

Here, the inlet narrowing portion 112 is located closer to the other end than the first end, and the surface inclination of the second inlet space portion 116 is formed to be gentler than the surface inclination of the first inlet space portion 114.

The discharge space 210 of the discharge tube 200 is formed of a discharge narrowing part 212, a first discharge space part 214 and a second discharge space part 216.

The first discharge space portion 214 is formed in a streamlined shape with the cross-sectional area gradually increasing toward one end with reference to the discharge narrow portion 212. The discharge narrower portion 212 has the smallest cross-

The second discharge space 216 is inclined with respect to the discharge narrow portion 212 so that the cross-sectional area gradually increases toward the other end.

Here, the sectional area of the discharge narrow portion 212 is formed to be smaller than the sectional area of the inlet narrow portion 112.

The coupling means 300 comprises an inlet coupling block 310 and an inlet thread 320, an outlet coupling tube 330 and a discharge thread 340, as shown in FIG.

The inflow coupling block 310 is protruded along the outer circumferential surface of the inflow pipe 100 and the inflow thread 320 is formed along the outer circumferential surface of the inflow coupling block 310.

The discharge coupling pipe 330 is surrounded on the outside of the inlet coupling block 310 and extends to the discharge pipe 200 so as to form a charge space portion 302 with the inlet pipe 100.

The discharge threads 340 are formed along the inner circumferential surface of the discharge coupling tube 330 to correspond to the inlet threads 320.

A plurality of guide jaws 350 are further formed along the end of the supercharging space 302 where the supercharging hole 304 is formed so that the circulating gas is introduced into the inflow space 110 or the discharge space 300 through the supercharging hole 304, (210).

The guide protrusion 350 may be formed parallel to the central axis of the inlet pipe 100 or the outlet pipe 200, or may be inclined in one direction or arc-shaped in one direction.

Further, the discharge coupling pipe 330 is provided with a supercharging supply hole 306 for supplying a circulating gas to the supercharging space 302.

6, the cross-sectional area of the boost space portion 302 decreases from the one end portion 302a where the supercharging supply hole 306 is formed to the other opposite end portion 302b with respect to the central axis of the inflow pipe 100 And is formed to gradually decrease.

6, one end portion 302a is an upper end portion and the other end portion 302b is a lower end portion with respect to the center axis of the inflow pipe 100. [

This is an embodiment, and it is natural that the positions of the one end 302a and the other end 302b are changed occasionally.

The adjusting means 400 comprises a tube 410 and a pump 420, as shown in FIG.

The tube 410 is located in the supercharging space portion 302 and contracted and expanded and the pump 420 regulates the inner pressure of the tube 410 to expand or contract the tube 410, ).

8, the adjusting means 400 'of the other embodiment is composed of the adjusting block 410' and the adjusting hole 420 ', the adjusting bolt 430' and the adjusting spring 440 ' .

The control block 410 'is located in the boost space portion 302, and a plurality of control holes 420' are formed in the inlet coupling block 310, and threads are formed along the inner circumferential surfaces.

The adjusting bolt 430 'is fastened to the adjusting hole 420' and the adjusting spring 440 'connects the adjusting block 410' to the adjusting bolt 430 ' In the direction of the bolt 430 '.

When the adjusting bolt 430 'is moved in the direction of the boosting hole 304 of the supercharging space 302, the adjusting block 410' The size of the charge space portion 302 is reduced.

On the contrary, when the adjustment bolt 430 'moves in the direction opposite to the boosting direction, the adjustment block 410' is moved to increase the size of the boost space portion 302, and the adjustment spring 440 ' 410 'in the direction of the adjustment bolt 430'.

As shown in FIG. 9, the guide part 500 is further provided in any one of the inflow space part 110 and the discharge space part 210.

The guide portion 500 is fixed to the inflow pipe 100 or the discharge pipe 200 by a plurality of wings 520 having a constant interval and a conical body 510.

Here, the plurality of vanes 520 may be formed parallel to the center axis of the inlet pipe 100 or the outlet pipe 200, or be inclined in one direction or arc-shaped in one direction.

Further, a fluororesin coating layer is formed on the inner surfaces of the inflow space portion 110, the discharge space portion 210, and the charge space portion 302.

The fluororesin coating layer minimizes the frictional force on the inner surface of each space part, thereby removing the back pressure and blowing the gas quickly.

Further, a heating unit 600 for heating the air blower unit 10 is further provided.

The heating unit 600 is provided in the adjusting unit 400 or along the outer circumference of the inlet pipe 100 and the outlet pipe 200.

First, as shown in FIG. 10, the heating unit 600 provided in the adjusting unit 400 is provided in the adjusting unit 400 to heat the air blower unit 10.

The heating unit 600 mainly includes a supercharging space 302 adjacent to the supercharging hole 304 and a second inflow space 216 of the inflow pipe 100 and a second inflow space 216 of the inflow pipe 200, So that the adsorption of the fine particles on the inner surfaces of the respective space portions can be prevented and minimized.

11, the space portion is heated along the outer periphery of the inflow pipe 100 and the discharge pipe 200 according to another embodiment of the heating unit 600. As shown in FIG.

The heating unit 600 heats the inflow space 110 and the discharge space 210 to prevent and minimize the adsorption of the fine particles.

The heating unit 600 generates heat by an applied power source. In one embodiment, a silicon rubber heater may be used.

The air blower unit 10 can be used in a semiconductor process or an LCD process. The air blower unit 10 quickly discharges the gas in the chamber, thereby eliminating the corrosion of the blowing fan used in the conventional semiconductor process or LCD process, Thereby preventing the generated fine material from adhering.

10: Air blower unit 100: Inflow pipe
200: discharge pipe 300: engaging means
302: Charging space 304: Charger
306: Supercharging supply hole 350: Guide chin
400, 400 ': adjusting means 500: guide portion
600: heating section

Claims (10)

An inflow pipe having an inflow space portion therein for inflowing gas;
A discharge pipe having a discharge space portion communicating with the inflow space portion and discharging the gas introduced into the inflow pipe;
The other end of the inflow pipe is spaced apart from the other end of the inflow pipe by a predetermined distance so as to form a supercharging space between the inflow pipe and the discharge pipe, A coupling means for coupling the coupling members; And
And adjusting means for controlling the amount of the circulating gas discharged to the discharge space portion through the supercharging ball by adjusting the space size of the supercharging space portion,
When the circulating gas is supplied to the supercharging space portion, pressure is generated as it is discharged to the discharge space portion through the supercharging ball, and the gas is introduced into the inflow space portion of the inflow pipe and discharged together with the supplied circulating gas.
Wherein the regulating means adjusts the discharge amount of the circulating gas to regulate the amount of exhaust gas flowing into the inflow pipe and discharged to the discharge pipe to a desired amount to be set.
The inflow pipe according to claim 1,
An inlet narrowest section having the smallest sectional area;
A first inflow space part whose surface is inclined so that the cross-sectional area gradually increases toward the one end with reference to the inflow narrowing part; And
And a second inflow space part whose inclined surface is gradually increased in cross section toward the other end with reference to the inflow narrowing part,
Wherein the inlet narrow portion is positioned closer to the other end than the one end, and the surface inclination of the second inlet portion is formed to be gentler than the surface inclination of the first inlet portion.
The discharge tube according to claim 2,
A discharge narrowing portion having the smallest cross-sectional area;
A first discharge space part formed in a streamline shape, the sectional area being gradually increased toward the one end with reference to the discharge narrow part; And
And a second exhaust space portion whose inclination is inclined so that the cross-sectional area gradually increases toward the other end with reference to the exhaust narrow portion.
The method of claim 3,
Wherein a cross-sectional area of the exhaust narrower portion is formed to be smaller than a cross-sectional area of the inlet narrow portion.
2. The apparatus according to claim 1,
An inlet coupling block protruding along an outer circumferential surface of the inlet pipe;
An inflow thread formed along an outer circumferential surface of the inlet coupling block;
A discharge coupling pipe extending from the discharge pipe to surround the outside of the inflow coupling block and forming the boost space between the inflow pipe and the inflow pipe; And
And a discharge thread formed along an inner circumferential surface of the discharge coupling tube to correspond to the inflow thread.
6. The method of claim 5,
Wherein the discharge coupling pipe is provided with a supercharging supply hole for supplying a circulating gas to the supercharging space portion,
Wherein the cross-sectional area of the supercharging space portion is gradually decreased from one end of the supercharging supply hole toward the other opposite end of the inflow pipe relative to the central axis of the inflow pipe.
2. The apparatus of claim 1,
A tube positioned in the boost space section; And
And a pump for adjusting the size of the boost space part by adjusting the internal pressure of the tube to expand or contract the internal space of the tube.
2. The apparatus of claim 1,
An adjustment block located in the boost space part;
A plurality of inlet holes formed in the inlet coupling block and having threads formed along the inner circumferences thereof;
An adjusting bolt fastened to the adjusting hole; And
And an adjusting spring for connecting the adjusting block with the adjusting bolt and closely contacting the adjusting block in the direction of the adjusting bolt,
Wherein when the adjusting bolt is moved in the direction of the boosting space of the boosting space portion, the adjustment block is moved in the boosting hole direction to reduce the size of the boosting space portion,
Characterized in that when the adjusting bolt is moved in the direction opposite to the supercharging ball, the adjusting block is moved so as to increase the size of the supercharging space, and the adjusting block is brought into close contact with the adjusting bolt in the direction of the adjusting bolt unit.
The method according to claim 1,
Wherein a fluororesin coating layer is formed on each of the inflow space, the discharge space, and the heating space.
The method according to claim 1,
Further comprising a heating unit for heating the air blower unit.

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