KR20190089424A - Fog Elimination Apparatus - Google Patents

Abstract

The present invention relates to a fog evaporating apparatus capable of removing fog by taking air from the atmosphere when fog occurs and discharging the air separately as warm air and cold air. The fog evaporating apparatus includes: a vortex part receiving compressed air flowing in through an air pump part and generating a vortex to separate the air into warm air and cold air, and then, discharging the warm air and the cold air through different outlets; a cold air pipe part installed beside a cold air outlet of the vortex part to move the cold air; a warm air pipe part installed beside a warm air outlet of the vortex part to move the warm air; and a dual-pipe part comprising an inner pipe connected to an end of the cold air pipe part to move the cold air and an outer pipe surrounding the inner pipe and connected to an end of the warm air pipe part to move the warm air to discharge moisture from the warm air by exchanging heat between the warm air and the cold air, and then, discharging the cold air and the dried warm air.

Description

Fog Elimination Apparatus

More particularly, the present invention relates to a device for removing fog, and more particularly, to a device for removing fog by collecting moisture in hot air according to the structure of a double pipe, To the fog dissipating device.

Although the accuracy of forecasting of rainfall and snowfall is increasing due to the high accuracy of Korea 's weather forecast, the weather forecast of this weather forecast remains at a broad level but does not predict a small weather condition in a specific area.

For example, it has not been predicted whether a fog occurs in a foggy area such as a mountainous section of Yeongdong Expressway, and the fog is not generated continuously, but rather occurs in a short time. It is not easy to do.

Therefore, in the case of the driver, since the countermeasures such as reducing the traveling speed and lighting the fog light when passing through the fog area, accidents occur continuously in the fog area.

In addition, obstacles due to various environmental factors usually occur on the road. Such obstacles can result in interference with the operation of cars or airplanes that are traveling on the road, and can lead to accidents in the worst case.

Especially, it is the fog which occurs most frequently among the obstacles that occur on the road and acts as a big obstacle. The fog is caused by the humidity in the air and the temperature around the road and the temperature difference on the road. Therefore, it is necessary to develop a technology that can effectively remove such fog.

Conventional fog removal methods have been proposed such as a method of using chemicals, a method of installing a structure on a roadway, and a method of spreading mist by hot air.

However, in the case of removing the fog by using a chemical agent (Korean Patent Laid-Open No. 10-2011-0139831), there is a disadvantage in terms of cost of chemicals and possibility of harm to human body.

In addition, in the case of a method of removing fog on the road using hot air (Korean Patent Laid-Open No. 10-2012-0088177), since the entire fog of the road must be blown with a hot air blower, The energy is relatively large and the driver of the vehicle traveling on the road may feel inconvenience due to the hot air of high temperature.

In addition, in the case of removing the mist by installing a mist shielding film on the roadway, there is a disadvantage that a dynamic moving apparatus such as the development and recovery of the shielding membrane must be accompanied by the influence of strong wind or the like. And the barrier structure itself is complicated and the load is increased.

As a result, there is a need to develop a technology capable of effectively removing fog formed on a road on which a vehicle or the like is traveling while solving the drawbacks of the above-described conventional techniques.

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

Disclosure of the Invention The present invention has been made to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide a vortex tube for separating air containing moisture into cold air and warm air and then collecting moisture contained in the warm air Which is low in cost and can be effectively removed in a harmless manner to the human body.

According to an aspect of the present invention, there is provided a fog dissipating apparatus comprising:

An air pump unit for compressing and supplying outside air of the mist generation area;

A vortex portion for receiving the compressed air flowing through the air pump portion to generate a vortex, classifying the vortex into warm air and cold air, and discharging the compressed air to different air outlets;

A cold air tube unit mounted on the cold air discharge side of the vortex unit and moving the cold air;

A warm air pipe portion mounted on the warm side of the vortex portion to move the warm air; And

And an outer tube which is connected to one end of the cold air circulation tube and moves the cool air, and an outer tube which surrounds the inner tube and is connected to one end of the warm air tube to heat-exchange the warm air and the cool air, A double pipe portion for discharging the warmth and the cool air from which the moisture is removed;

And a control unit.

The vortex portion includes:

An air inlet through which the compressed air flows;

A vortex chamber in which a plurality of radially formed arcs are formed to convert the air introduced through the air inlet into a vortex;

The vortex chamber is formed at a central portion, one side is a cold air exhaust port, and the other side is a warm air exhaust port. A vortex tube for dividing a vortex formed by the vortex chamber into a cold air and a warm air and separately discharging the air into a cold air outlet and a warm air outlet; And

And a control valve installed on the warm exhaust port to regulate the amount of exhaust of the warm exhaust port to control the separation and discharge of warm and cool air.

The vortex portion includes:

And a humidity sensor for detecting humidity included in the warmer and disposed on the warm exhaust port side for generating an opening / closing control signal of the control valve so as to minimize moisture contained in the warm air discharged through the warm air outlet, And the like.

The fog dissipating device includes:

And a moisture collecting unit collecting the moisture contained in the warm air discharged from the double tube and measuring the amount of the moisture.

The fog dissipating device includes:

Further comprising a fog detecting section for detecting a fog around,

And to perform a fog dissipating operation when a fog is detected by the fog detecting unit.

The present invention having the above-described configuration is characterized in that a vortex tube is used to separate air containing moisture into cold air and warm air, and then moisture contained in the warm air side can be collected using a double tube, Thereby providing an effect of effectively removing it in a harmless manner to the human body.

1 is a schematic block diagram of a fog dissipating apparatus according to an embodiment of the present invention.
2 is a view showing the internal configuration of the vortex portion.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of a fine dust removing apparatus using a vortex tube and an air cleaning system using the same according to the present invention will be described with reference to the accompanying drawings.

Hereinafter, it is to be noted that the following description is only an embodiment for carrying out the present invention, and the present invention is not limited to the contents of the embodiments described below.

In the following description of the embodiments of the present invention, parts that are the same as or similar to those of the prior art, or which can be easily understood and practiced by a person skilled in the art, It is important to bear in mind that we omit.

In order to dissipate fog with a simple configuration and a low cost as described later, the present invention provides a vortex tube configured to generate a vortex in the air to be input and separate the high temperature air and the low temperature air, (Vortex Tube), the outside air is injected into the vortex tube, so that the outside air passes through the vortex tube and is separated into warm air and cold air, and again the double tube is used to collect the moisture contained in the warm air. To a fog dissipating device using a vortex tube that is configured to improve the effect of fog dissipation with a simple configuration and at low cost without requiring any additional power.

Next, with reference to the drawings, the details of the fog dissipating apparatus 100 using the vortex tube according to the present invention will be described.

1 is a schematic configuration diagram of a fog dissipating apparatus 100 according to an embodiment of the present invention.

1, the fog dissipating apparatus 100 includes a fog detecting unit 101 for detecting a fog, an air pump unit 110, a vortex unit 120 connected to the air pump unit 110 through an inlet pipe, A cool air duct 130 communicating with the cool air exhaust port 127 of the vortex unit 120 to discharge cool air and a cool air duct 130 communicating with the warm air exhaust port 128 of the vortex unit 120 to discharge warm air, A double tube part 150 for removing moisture and combining warm air and cold air by joining the cold air tube part 130 and the warm air tube part 140 to each other and for collecting the moisture removed from the double tube part 150; And a moisture collecting unit (160).

The fog detecting unit 101 is configured to detect the presence or absence of fog by detecting a visual distance or a humidity below a dew point included in the air, and outputting the detected fog.

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

The vortex unit 120 receives the compressed air flowing through the air pump unit 110, generates vortexes, and classifies the compressed air into warm air and cold air, and then discharges the air into different vents. The vortex unit 120 is configured to convert the compressed air into a vortex, and then classify and discharge the compressed air into a cool air and a warm air.

The cold air tube part 130 is mounted on the cold air discharge side of the vortex part 120 to discharge the cold air.

The warm air duct 140 is mounted on the warm discharge side of the vortex portion 120 to discharge the warm air.

The double pipe 150 is composed of an inner pipe 152 and an outer pipe 154. The inner pipe 152 is connected to a first connecting member 156 at one end of the cold air cooling pipe 130 to move the cold air. The outer tube 154 surrounds the inner tube 152 and is connected to a second connection member 158 at one end of the warm air tube 140 to move the warmer. The double pipe 150 discharges the moisture contained in the warmer by exchanging heat between the warmer moving through the inner pipe 152 and the cooler moving through the outer pipe 153, .

The moisture collector 160 is configured to collect moisture removed from the dual tube portion 150. The moisture collector 160 is connected to the dehumidified warm portion of the double tube portion 150 and the portion where the cool air is discharged to collect the moisture contained in the warm portion and measure the amount of the moisture.

The fog diffusing apparatus 100 of FIG. 1 will be described with reference to the components. The fog detecting unit 101 detects the occurrence of fog in the atmosphere. Here, when the fog detecting unit 101 detects that fog occurs, the air pump unit 110 sucks the air in the air, compresses the air, and supplies the compressed air to the vortex unit 120. The vortex portion 120 receives compressed air and generates a vortex to be classified into warm air and cold air. Thereafter, the cold air moves in the cold air tube part 130 connected to one end of the vortex part 120. In addition, the warm air moves in the warm air tube portion 140 connected to the other end of the vortex portion 20. [ The outer tube 154 is connected to one end of the cold air tube 130 and surrounds the inner tube 152 through which the cool air moves and the outer tube 154 connected to one end of the warm air tube 140 to surround the inner tube 152, The double tube portion 150 discharges the moisture contained in the warmer by heat exchange between the warmer and the cooler, and discharges the warmer and the cooler. In addition, the moisture collector 160 is connected to one side of the double tube part 150 to collect the moisture contained in the warmer and measure the amount of the moisture.

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

2, the vortex unit 120 includes an air inlet 123 through which compressed air flows, a vortex chamber 125 through which an air inlet 123 is connected to one side to convert the introduced air into a vortex, The vortex generated by the chamber 125 is divided into the cold air and the warm air and the exhaust amount of the vortex tube 121 and the warm air exhaust port 128 for separately separating and discharging the cold air and the warm air into the cold air exhaust port 127 and the warm air exhaust port 128, And a regulating valve 129 for regulating the separation and discharge of the exhaust gas.

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

In the vortex tube 121, the vortex chamber 125 is formed at a central portion thereof, one side thereof serves as a cold air exhaust port 127, and the other side thereof is formed by a warm air exhaust port 128. The vortex chamber 125 having the above-described structure divides vortices formed therein into cold air and warm air, and separates and discharges them into the cold air exhaust port 127 and the warm air exhaust port 128, respectively.

The control valve 129 is provided on the warm exhaust port 128 to regulate the amount of exhaust of the warm exhaust port 128 to control the separation and discharge of warm and cool air.

The vortex portion 120 may be provided on the warm exhaust port 128 side to generate an opening / closing control signal for the control valve 129 to minimize moisture contained in the warmed air discharged through the warm exhaust port 128 And a humidity sensor 122 for detecting humidity included in the warmth and outputting humidity information.

The operation of the vortex portion 120 having the above-described structure will be described. A free vortex is generated on the wall surface of the channel by the forced vortex generation due to the tangential entrance velocity of the vortex chamber 125. In the forced vortex region, , The temperature of the forced vortex region drops due to the transfer of the momentum, and the heat transfer from the free vortex region to the forced vortex region occurs due to the temperature difference. At this time, since the transfer of the momentum is very large compared to the heat transfer, Heat transfer), resulting in energy separation in the tube.

It should be noted that a more detailed description of the operation principle of the vortex tube as described above is obvious to a person skilled in the art through the literature of the prior art, and thus a detailed description thereof has been omitted here for brevity .

As described above, the vortex tube is a device capable of separating the high-pressure flow into two low-pressure flows having different temperatures. The vortex tube is used as a cooling and heating device due to the energy separation effect, And is also utilized as a device for separating fine particles such as exhaust gas.

Although the configuration of the mist diffuser 100 is not shown in FIGS. 1 and 2, it is controlled by a controller (not shown) provided to control the operation of the mist diffuser 100 It is self-evident. The control unit (not shown) compares the humidity information detected by the humidity sensor 122 of the vortex unit 120 with the amount of moisture collected by the moisture collector 160, It is possible to judge whether or not the driving is properly performed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

100: Fog dissipating device
101: Fog detection unit
120: Vortex part
121: Vortex tube
122: Humidity sensor
123: Air inlet
125: Vortex chamber
127: Cool air exhaust
128: Warm air exhaust
129: Regulating valve
130: cold air tube
140: Warm air tube
150: double tube
152: Inner pipe
154: Appearance
156: first connecting member
158: second connecting member
160: Moisture collector

Claims (5)

An air pump unit for compressing and supplying outside air of the mist generation area;
A vortex portion for receiving the compressed air flowing through the air pump portion to generate a vortex, classifying the vortex into warm air and cold air, and discharging the compressed air to different air outlets;
A cold air tube unit mounted on the cold air discharge side of the vortex unit and moving the cold air;
A warm air pipe portion mounted on the warm side of the vortex portion to move the warm air; And
And an outer tube which is connected to one end of the cold air cooling tube and moves the cool air and which is connected to one end of the warm air tube and surrounds the inner tube to exchange heat between the warmer and the cooler to discharge moisture contained in the warmer A double pipe portion for discharging the warmth and the cool air from which the moisture is removed;
The fog dissipating device comprising:
[2] The vortex generator according to claim 1,
An air inlet through which the compressed air flows;
A vortex chamber in which a plurality of radially formed arcs are formed to convert the air introduced through the air inlet into a vortex;
The vortex chamber is formed at a central portion, one side is a cold air exhaust port, and the other side is a warm air exhaust port. A vortex tube for dividing a vortex formed by the vortex chamber into a cold air and a warm air and separately discharging the air into a cold air outlet and a warm air outlet; And
And a control valve installed on the warm exhaust port to regulate the amount of exhaust of the warm exhaust port to control the separation and discharge of warm and cool air.
[3] The vortex generator according to claim 2,
And a humidity sensor for detecting humidity included in the warmer and disposed on the warm exhaust port side for generating an opening / closing control signal of the control valve so as to minimize moisture contained in the warm air discharged through the warm air outlet, Further comprising a fog dissipating device.
The method according to claim 1,
And a moisture collecting unit collecting the moisture contained in the warm air discharged from the double tube portion and measuring the amount of the moisture.
The fog dissipating apparatus according to claim 1,
Further comprising a fog detecting section for detecting a fog around,
And to perform a fog dissipating operation when a fog is detected by the fog detecting unit.

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