KR102097658B1 - Fog Elimination Apparatus - Google Patents

Abstract

The present invention relates to a fog dissipation device that can remove the fog by introducing air in the atmosphere when the fog is generated and separating it into hot air and cold air.
The above-mentioned mist dissipation device comprises: a vortex unit that receives compressed air flowing through the air pump unit, generates vortex, classifies it as warm and cold, and discharges it to different exhaust ports; A cold air pipe part mounted on the cold air discharge side of the vortex part to move the cold air; A warm air pipe part mounted on a side of the vortex unit to discharge the warm air; And connected to one end of the cold air pipe part, surrounds the inner tube and the inner tube through which the cold air moves, and is connected to one end of the warm air pipe part to form an appearance in which the warm air moves to exchange heat between the warm air and the cold air to absorb moisture contained in the warm air. It is characterized in that it is configured to include; double pipe portion for discharging, and discharging the warm air and the cold air from which the moisture is removed.

Description

Fog Elimination Apparatus

The present invention relates to an apparatus for removing fog, and more specifically, when fog occurs, the air is introduced into the atmosphere and separated into hot air and cold air, thereby collecting fog by collecting moisture in hot air according to a double pipe structure. It relates to a mist dissipation device that can be removed.

In recent years, the accuracy of forecasts in rainfall, snowfall, etc. has increased due to the very high accuracy in recent years, but the weather forecasts of such forecasts remain at a wide range, but cannot predict the small-scale weather conditions in a specific area.

For example, it is unforeseen whether fog has occurred in a fog-prone area, such as a mountainous section of the Yeongdong Expressway, and it is also known in advance because the fog often occurs in an instant rather than continuously. It is not easy to do.

Therefore, from the driver's point of view, when driving through the fog area, measures such as reducing the driving speed and lighting the fog light are all in place, so that accidents in the fog generating area are constantly occurring.

In addition, obstacles due to various environmental factors are generally generated on the road. Due to these obstacles, a car or an airplane traveling on the road may be disturbed by driving, and at worst, it may lead to an accident.

In particular, fog is the most frequently occurring obstacle on the road and acts as a major obstacle. Fog is caused by the humidity in the air and the temperature difference between the road and the road. Therefore, there is a need to develop a technology capable of effectively removing such fog.

Existing fog removal methods have been proposed, such as using chemicals, installing structures on roadsides, and spreading fog with hot air.

However, in the case of a method of removing fog using a chemical agent (Korean Patent Publication No. 10-2011-0139831, etc.), there are disadvantages in terms of chemical cost and human injury potential.

In addition, in the case of a method of removing fog on the road using a hot air blower (Korean Patent Publication No. 10-2012-0088177, etc.), the fog to be blown over the whole road must be blown with a hot air blower, so the area to be in charge is very large, and There is a disadvantage in that energy is relatively large, and a driver, such as a vehicle driving on the road, may feel uncomfortable due to hot air.

In addition, in the case of a method of removing fog by installing a fog barrier on a roadside, there is a disadvantage that a dynamic moving device such as deployment and recovery of the barrier must be accompanied by the influence of strong wind. In addition, the barrier film structure itself is complex and involves a number of problems, such as an increase in load.

As a result, it can be said that the development of a technology capable of effectively removing fog formed on a road on which a vehicle runs is solved while solving the disadvantages of the prior art described above.

1. Korea Patent Publication No. 10-2011-0139831 2. Korean Patent Publication No. 10-2012-0088177

The present invention is to solve the problems of the prior art as described above, by applying a vortex tube to separate the air containing moisture into cold and warm air, and then collect the moisture contained on the warm side using a double tube It is an object of the present invention to provide a fog dissipation device that can effectively remove fog in a low-cost and harmless manner.

The fog dissipation device of the present invention for achieving the above object,

An air pump unit compressing and supplying external air in the fog generating area;

A vortex unit that receives compressed air flowing through the air pump unit, generates vortices, classifies it as warm and cold, and discharges it to different exhaust ports;

A cold air pipe part mounted on the cold air discharge side of the vortex part to move the cold air;

A warm air pipe part mounted on a side of the vortex unit to discharge the warm air; And

It is connected to one end of the cold air pipe part and surrounds the inner tube through which the cold air moves and the inner tube, and is connected to one end of the warm air pipe part to form an appearance in which the warm air moves so that the warm air and the cold air exchange heat to discharge moisture contained in the warm air. And, the double pipe portion for discharging the warm air and the cold air is removed from the moisture;

Characterized in that it comprises a.

The vortex portion,

An air inlet through which the compressed air flows;

A vortex chamber in which a plurality of ribs formed in a radial arc shape are formed to convert air introduced through the air inlet into a vortex;

The vortex chamber is formed in the central portion, one side is a cold air exhaust, and the other side is a warm air exhaust. A vortex tube that separates and discharges the vortices formed by the vortex chamber into cold air and warm air, respectively, by dividing them into cold air and warm air; And

It may be configured to include a; provided on the side of the warm air exhaust control valve for adjusting the exhaust of the warm air exhaust to separate the discharge of warm air and cold air.

The vortex portion,

A humidity sensor for detecting humidity included in the warm air installed on the side of the warm air exhaust and outputting humidity information to generate an opening / closing control signal of the control valve to minimize moisture contained in warm air discharged through the warm air exhaust; It may be configured to include more.

The fog dissipation device,

It may be configured to further include a moisture collecting portion for collecting the moisture contained in the warmth discharged from the double pipe portion and measuring the amount of moisture.

The fog dissipation device,

Further comprising a fog detection unit for detecting the surrounding fog,

When fog is detected by the fog detector, it may be configured to perform a fog dissipation operation.

The present invention having the above-described configuration, by applying a vortex tube to separate the air containing moisture into cold and warm air, and then using a double tube to collect the moisture contained in the warm side by using a double tube, the fog is low cost, It provides an effect that can be effectively removed in a harmless manner to the human body.

1 is a schematic configuration diagram of a mist dissipation device according to an embodiment of the present invention.
2 is a view showing the internal configuration of the vortex portion.

Hereinafter, specific embodiments of the apparatus for removing fine dust using a vortex tube and an air purification system using the same will be described with reference to the accompanying drawings.

Here, it should be noted that the contents described below are only one embodiment for carrying out the present invention, and the present invention is not limited to the contents of the embodiments described below.

In addition, in the following description of the embodiments of the present invention, the same or similar to the contents of the prior art, or a portion determined to be easily understood and practiced at the level of those skilled in the art, for the sake of brevity, the detailed description It should be noted that is omitted.

In addition, the present invention, as described later, in order to be able to dissipate the fog with a simple configuration and low cost, by generating a vortex in the input air and vortex tube configured to be separated into high-temperature air and low-temperature air to output Using the principle of (Vortex Tube), by injecting external air into the vortex tube, the outside air passes through the inside of the vortex tube and is separated into warm and cold, and again, the double tube is used to collect the moisture contained in the warmth. By being configured, it relates to a fog dissipation device using a vortex tube configured to improve the fog dissipation effect with a simple configuration and low cost without the need for a separate power.

Subsequently, with reference to the drawings, detailed contents of the fog dissipation device 100 using a vortex tube according to the present invention will be described.

1 is a schematic configuration diagram of a mist dissipation device 100 according to an embodiment of the present invention.

As shown in FIG. 1, the fog dissipation device 100 includes a fog detection unit 101 for detecting fog, an air pump unit 110, and a vortex unit 120 connected to the air pump unit 110 through an inlet pipe. ), Is installed in communication with the cold air exhaust 127 side of the vortex unit 120 to discharge the cold air pipe 130, the warm air exhaust port 128 of the vortex portion 120 is installed in communication to discharge the warmth The hot air pipe part 140, the cold air pipe part 130 and the warm air pipe part 140 are combined to remove moisture and collect the moisture removed from the double pipe part 150 and the double pipe part 150 for discharging warm air and cold air. It comprises a moisture collecting unit 160.

The fog detection unit 101 is configured with a vision system or a humidity sensor, and is configured to detect the presence or absence of fog by detecting humidity within a viewing distance or a dew point included in the air, and then output it.

The air pump unit 110 is configured to suck air in the atmosphere and compress it, and then supply it to the vortex unit 120 when fog occurs.

The vortex unit 120 is configured to receive compressed air introduced through the air pump unit 110 to generate vortices, classify them as warm and cold, and then discharge them to different exhaust ports. The vortex unit 120 is configured to convert compressed air into vortex and then sort and discharge it into cold and warm air.

The cold air pipe unit 130 is mounted on the cold air discharge side of the vortex portion 120 and configured to discharge the cold air.

The warm air pipe part 140 is mounted on the warm air discharge side of the vortex part 120 and is configured to discharge the warm air.

The double pipe 150 is composed of an inner pipe 152 and an exterior 154. The inner pipe 152 is coupled to the first connection member 156 at one end of the cold air pipe unit 130 and configured to move the cold air. The exterior 154 surrounds the inner tube 152 and is coupled to a second connecting member 158 at one end of the warm air pipe part 140 to be configured to move the warmth. The double pipe 150 heats the cold moving the inner pipe 152 and the warm air moving the exterior 154 to discharge moisture contained in the warm air, and the warm air and the cold air from which the moisture has been removed are removed. It is configured to discharge.

The moisture collection unit 160 is configured to collect moisture removed from the double pipe unit 150. The moisture collecting unit 160 is connected to a portion where the moisture is removed from the double pipe unit 150 and the cold air is discharged to collect moisture contained in the warmth and measure the amount of moisture.

When the fog dissipation device 100 of FIG. 1 described above is described according to components, the fog detection unit 101 detects the presence or absence of fog in the air. Here, when the fog detection unit 101 detects that fog has occurred, the air pump unit 110 inhales and compresses air in the atmosphere and supplies it to the vortex unit 120. The vortex unit 120 is classified into warm and cold by generating compressed air by receiving compressed air. After this, the cold air moves from the cold air pipe unit 130 connected to one end of the vortex unit 120. In addition, the warm air moves from the warm air pipe part 140 connected to the other end of the vortex part 20. Connected to one end of the cold air pipe part 130, the inner tube 152 through which the cold air moves and the inner tube 152 are wrapped and connected to one end of the warm air pipe part 140 to be formed of the outer surface 154 through which the warm air moves. The double pipe part 150 exchanges the warm air with the cold air to discharge moisture contained in the warm air, and discharges the warm air from which the moisture is removed and the cold air. In addition, the moisture collecting part 160 is connected to one side of the double pipe part 150 to collect the moisture contained in the warmth and measure the amount of the moisture.

2 is a view showing the internal configuration of the vortex portion 120 of Figure 1 according to an embodiment of the present invention.

As shown in FIG. 2, the vortex part 120 is a vortex chamber 125 that converts the inflowing air into a vortex by combining the air inlet 123 and the air inlet 123 through which compressed air flows into one side, vortex The vortices formed by the chamber 125 are classified into cold and warm air, and the exhaust volumes of the vortex tube 121 and the warm air exhaust 128 that are separately discharged into the cold air exhaust 127 and the warm air exhaust 128 are controlled to warm and cool the air. It may be configured to include a control valve 129 for controlling the discharge of the separation.

In the above configuration, a plurality of ribs are formed in the vortex chamber 125 in a radial arc shape. The air introduced through the air inlet 123 by the plurality of ribs described above is converted into a vortex to move in the vortex tube 121.

And the vortex tube 121, the vortex chamber 125 is formed in the central portion, one side is formed of a cold air exhaust 127, the other side is formed of a warm air exhaust (128). The vortex chamber 125 having the above-described configuration divides and discharges the vortices formed therein into cold air and warm air, respectively, and separates them into the cold air exhaust 127 and the warm air exhaust 128.

In addition, the control valve 129 is installed on the side of the warm air exhaust 128 to control the amount of exhaust of the warm air exhaust 128 to control the separation and discharge of warm and cold air.

In addition, the vortex part 120, the side of the warm air exhaust port 128 for generating an opening and closing control signal of the control valve 129 to minimize the moisture contained in the warm air discharged through the warm air exhaust port 128 It may be configured to further include a humidity sensor 122 that detects the humidity contained in the installed warm air and outputs humidity information.

When explaining the operating principle of the vortex unit 120 having the above-described configuration, free vortex is generated on the wall of the conduit by generating vortex by the entrance velocity in the tangential direction of the vortex chamber 125, and free vortex area in the forced vortex area As the temperature of the forced vortex region decreases due to the momentum transfer, heat transfer occurs from the free vortex region to the forced vortex region due to this temperature difference. Heat transfer), and consequently an energy separation phenomenon occurs in the tube.

Here, more detailed contents of the operating principle of the vortex tube as described above are obvious to those skilled in the art through literatures of the prior art, and thus, for the sake of brevity, the detailed description is omitted here. .

As described above, the vortex tube is a device capable of separating high-pressure flow into two low-pressure flows with different temperatures, and is utilized as a cooling and heating device by this energy separation effect, and also, by a material separation effect It is also used as a fine particle separation device such as exhaust gas.

The configuration of the fog dissipation device 100 is not shown in the drawings of FIGS. 1 and 2, but is controlled by a control unit (not shown) provided to control the operation of the fog dissipation device 100. This is obvious. The control unit (not shown) compares the amount of moisture collected by the moisture collection unit 160 with the humidity information detected by the humidity sensor 122 of the vortex unit 120, and the mist dissipation device 100. It is possible to determine whether or not driving is properly performed.

As described above, the details of the fog dissipation device using the vortex tube according to the present invention have been described through the embodiments of the present invention as described above, but the present invention is not limited to the contents described in the above-described embodiments, and thus It is natural that the present invention is capable of various modifications, changes, combinations, and substitutions according to design needs and various other factors by those skilled in the art to which the present invention pertains.

100: fog dissipation device
101: fog detection unit
120: vortex part
121: vortex tube
122: humidity sensor
123: air inlet
125: vortex chamber
127: cold air exhaust
128: warm exhaust
129: regulating valve
130: cold air pipe
140: warm wind pipe
150: double pipe
152: inner tube
154: appearance
156: first connecting member
158: second connecting member
160: moisture collection unit

Claims (5)

An air pump unit compressing and supplying external air in the fog generating area;
A vortex unit that receives compressed air flowing through the air pump unit, generates vortices, classifies it as warm and cold, and discharges it to different exhaust ports;
A cold air pipe part mounted on the cold air discharge side of the vortex part to move the cold air;
A warm air pipe part mounted on a side of the vortex unit to discharge the warm air;
It is connected to one end of the cold air pipe part and surrounds the inner tube through which the cold air moves and the inner tube, and is connected to one end of the warm air pipe part to form an appearance in which the warm air moves, thereby discharging the moisture contained in the warm air by exchanging the warm air and the cold air. And, the double pipe portion for discharging the warm air and the cold air is removed from the moisture; And
A mist dissipation device comprising a moisture collecting part that collects moisture contained in the warmth discharged from the double pipe part and measures the amount of the moisture.
The method according to claim 1, wherein the vortex portion,
An air inlet through which the compressed air flows;
A vortex chamber in which a plurality of ribs formed in a radial arc shape are formed to convert air introduced through the air inlet into a vortex;
The vortex chamber is formed in the central portion, one side is a cold air exhaust, and the other side is a warm air exhaust. A vortex tube that separates and discharges the vortices formed by the vortex chamber into cold air and warm air, respectively, by dividing them into cold air and warm air; And
A mist dissipation device comprising a; control valve is installed on the side of the warm air exhaust to control the discharge of the warm air exhaust to control the separate discharge of warm and cold air.
The method according to claim 2, wherein the vortex portion,
A humidity sensor for detecting humidity included in the warm air installed on the side of the warm air exhaust and outputting humidity information to generate an opening / closing control signal of the control valve to minimize moisture contained in warm air discharged through the warm air exhaust; Mist dissipation device further comprising.
delete The method according to claim 1, The fog dissipation device,
Further comprising a fog detection unit for detecting the surrounding fog,
A fog dissipation device configured to perform a fog dissipation operation when fog is detected by the fog detection unit.

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