KR101215145B1 - Fog removal system by using Ubiquitous Sensor Network - Google Patents

Abstract

The present invention is a fog removal system using a USN to remove the mist using an aqueous solution mixed with an absorbent and water in the region where the fog occurs in the habitual, the temperature sensor and humidity sensor is installed in the habitually generated fog And a plurality of USN temperature and humidity sensor nodes which measure the ground temperature by embedding in the air temperature and humidity and the surface of the air through the USN network communication network to measure and transmit weather information of the temperature and humidity generated by the fog. Data analysis unit for receiving the temperature and humidity data measured through the USN temperature and humidity sensor node of the USN network communication network to determine whether the fog occurs by comparing the temperature and humidity requirements of the fog, and the fog Motor connected to the propeller by forming an aqueous solution spray nozzle in the blower Spraying an aqueous solution through the power of the to remove the condensation tuberculosis before the fog and mist particles after the occurrence of fog, fog removal means for reducing the humidity of the fog area and the temperature measured by the USN temperature and humidity sensor node through the data analysis unit If the humidity data meets the fog generation requirements, operate the fog removal means to remove the coagulation tuberculosis and fog particles before the fog is generated, and to control the fog removal means to reduce the humidity of the fog generation area by the absorbent. It provides a fog removal system using a USN, characterized in that consisting of a fog removal control unit.

Description

Fog removal system by using Ubiquitous Sensor Network}

The present invention compares temperature and humidity data to the occurrence of fog using a USN network communication network in a habitually occurring fog area, and determines whether the fog is generated based on the measured data to determine the absorbent and water in the fog area. Spray the aqueous solution particles mixed with the coagulation tube before the mist generation and the fog particles after the mist generation to increase the weight of the coagulation tube and the mist particles to remove the fog through free fall, and to reduce the humidity of the mist generating area by the absorbent More specifically, a USN temperature and humidity sensor node with a built-in temperature and humidity sensor is installed in a fog rushing area, and the temperature and humidity in the air are buried and the ground temperature is measured to compare the temperature and humidity data. It determines whether the fog occurs and automatically uses the USN network when the fog requirement is met. The aqueous solution particles mixed with the absorbent and water sprayed from the mist removing means by operating the dog removing means are combined with the coagulation nuclei before the mist generation and the fog particles after the mist generation, resulting in an increase in the weight of the combined aqueous solution particles and the coagulation and mist particles. The present invention relates to a mist elimination system using USN which removes mist by free fall and reduces humidity of a mist generating region by an absorbent.

Generally, fog occurs when condensation occurs due to water vapor in the air coming into contact with a cold water surface or the ground. In order to collect a large amount of very fine water droplets by gathering atmospheric water such as fog, the following conditions are required.

- A large amount of water vapor should be contained in the atmosphere.

- The air should be cooled below the dew point temperature.

- There should be plenty of condensation nuclei, which are hygroscopic fine particles that promote the formation of fine droplets in the atmosphere.

- There should be a supply of water vapor around

When the air is cooled under the above conditions, fog is generated. The causes of the cooling are radiative cooling, cooling by the temperature difference between the air temperature and the surface or the sea surface, and when the cold air is mixed with the air, the air rises. Cooling due to adiabatic expansion that occurs. The fog generated by the cooling itself is not tracked by on-time observation alone, has a property that cannot be observed regularly, the topographical characteristics are dominant, and the characteristics vary depending on the local topography and weather conditions of the area where the prediction is accurate. it's difficult.

Fog, which is a natural phenomenon caused by the sudden change of temperature, is the most dangerous factor that obstructs the driver's view on the road, and in fact, it causes huge obstacles to safe driving due to the fog, and thus the frequency of accidents is high and it is likely to increase due to chain collision. This is big.

The fog is a habitual fog area is generated in the highway section of the car is running, but the countermeasures are all to make the front clock better by using a fog in front of the car or flashing an emergency light. In the fog area, the same accidents were repeated every year, causing a lot of casualties.

In addition, Korea's climate is hot and humid in summer and cold in winter, and there are many topographical factors such as mountain slopes, reservoirs, coastal roads, and tunnels that pass through the mountains. There are many areas. As mentioned above, the fog countermeasure for the area where the fog occurs in a habitual manner is divided into four parts.

-Visual reinforcement by lighting

-Reinforcement by providing advance information using traffic safety signs

How to install a device to prevent lane departure

-Information transmission system to induce deceleration by providing weather change information to driver

As mentioned above, the fog countermeasure for the current fog area is caused by the fog, which makes the clock on the road bad and prepares the countermeasures to the driver through the above method, so that even if the driver knows this in advance and drives carefully, there is a risk of an accident. In addition, since the vehicle's running speed is very low, it interferes with the smooth traffic flow and acts as a congestion factor, causing economic loss. Therefore, it is necessary to develop a system capable of eliminating fog generated actively, rather than simply transmitting fog generation information.

The present invention has been made to solve the above problems by installing a USN temperature-humidity sensor node in a region where fog occurs in a habitual manner, buried in the air temperature and humidity and the ground surface to measure the temperature of the ground and measured By analyzing the temperature and humidity data, if the fog generation requirements are met in comparison with the temperature and humidity requirements that can cause fog, the mist elimination means is automatically driven through the USN network to prevent condensation before and after fog. Aqueous particles sprayed from the mist elimination means are combined with the particles to increase the weight of the coagulation nucleus and the fog particles to remove the coagulation nuclei and the fog particles through a free fall to prevent the occurrence of fog in advance, the fog generated when the fog occurs Particles can be removed and the humidity in the fog area can be reduced by the absorbent. The purpose is to provide a fog removal system using the USN.

Another object of the present invention is to provide a fog removing system using USN, in which the measurement of temperature and humidity data and the control of the fog removing means are wirelessly transmitted through a USN network communication network to automatically remove fog. have.

The present invention provides a fog removal system using a USN to remove the fog using an aqueous solution mixed with an absorbent and water in the area where the fog occurs in a habitual manner,

It is installed in the area where fog occurs regularly, and it is buried in the air temperature, humidity, and ground surface through temperature sensor and humidity sensor to measure the temperature of the ground, and the weather information of the temperature and humidity at which the fog occurs is generated by the USN network communication network. Multiple USN temperature and humidity sensor nodes for measurement and transmission;

A data analyzer to determine whether fog is generated by receiving temperature and humidity data measured through the plurality of USN temperature and humidity sensor nodes through a USN network communication network and comparing the temperature and humidity requirements to generate fog;

It is installed in the area where the fog occurs in a habitual manner to form an aqueous spray nozzle in the blower to spray the aqueous solution through the power of the motor connected to the propeller to remove the coagulation nuclei before the fog and the fog particles after the fog is generated, Reducing mist removing means;

When the temperature and humidity data measured by the USN temperature and humidity sensor node through the data analysis unit meets the fog generation requirements, by operating the fog removing means to remove the coagulation nuclei before the fog and the fog particles after the fog occurs, the fog by the absorbent A mist elimination control unit controlling the mist elimination means so as to reduce the humidity of a generation area; .

The present invention measures the temperature and humidity data of the fog generation requirements in the area where the fog occurs in the habitual use by using the USN network communication network, and determines whether the fog is generated by comparing with the fog generation requirements through the measured data. By spraying an aqueous solution particle mixed with a desiccant and water in the area where the fog occurs in a habitual manner, the coagulation nuclei before the fog is generated and the fog particles after the occurrence of the fog are combined with the aqueous solution particles to increase the weight of the coagulation tube and the fog particles to free fall. Through the removal of coagulation before the mist occurs, the generation of mist can be prevented in advance, the mist particles can be removed after the mist is generated, and the humidity of the mist-producing region can be reduced by the absorbent.

In addition, the present invention has the effect that the measurement of the temperature and humidity data and the control of the fog removing means wirelessly transmitted through the USN network communication network to automatically remove the fog through wireless communication.

1 is a perspective view of a fog removal system using a USN according to the present invention.
2 is a block diagram of a fog removing system using the USN according to the present invention.
Figure 3 is a block diagram of a USN temperature and humidity sensor node of the fog removal system using the USN according to the present invention.
4 is a view showing an embodiment of a fog removal system using a USN according to the present invention.

The present invention measures the occurrence of fog using a USN network communication network in a region where fog occurs in a habitual manner, and determines the occurrence of fog through the measured data to spray the aqueous particles mixed with the absorbent and water in the fog generation area Coagulation tuberculosis before sea fog generation and aqueous particles sprayed on the fog particles after the fog is combined to increase the weight of the coagulation tube and fog particles to remove the fog through free fall, reducing the humidity in the fog area due to the spray of the absorbent Hereinafter, with reference to the accompanying drawings in order to specifically describe the present invention will be described in detail.

1 is a perspective view of a fog removal system using a USN according to the present invention, Figure 2 is a block diagram of a fog removal system using a USN according to the present invention, Figure 3 is a USN of a fog removal system using a USN according to the present invention 4 is a block diagram of a temperature and humidity sensor node, and FIG. 4 is a diagram showing an embodiment of a fog removing system using USN according to the present invention.

As shown in FIG. 1 and FIG. 2, the present invention removes the mist by using an aqueous solution mixed with an absorbent and water in a region where the fog occurs in a habitual manner. A plurality of USN temperature and humidity sensor nodes (100) for embedding the temperature and humidity in the air to measure the temperature of the ground to transmit the temperature and humidity data to the data analysis unit 200 by wireless communication through the USN network communication network And the temperature and humidity data received from the USN temperature and humidity sensor node 100 through wireless communication, and comparing the measured temperature and humidity data with temperature and humidity data of a fog generation requirement set by the user. Data analysis unit 200 to determine whether the occurrence of the fog, and if the fog analysis requirements are met by determining whether the fog occurs in the data analysis unit 200 habitually fog Water spray nozzle in the blower and spray the aqueous solution mixed with the absorbent and water through the power of the motor connected to the propeller to remove the mist particles after the coagulation tube and the mist before the mist occurs. Fog removing means 300 for reducing the humidity of the spraying area through the injection, and if the fog analysis requirements to determine whether the fog occurs in the data analysis unit 200 operates the fog removing means 300 It is composed of a mist removing control unit 400 for controlling the mist removing means 300 to remove the mist.

The USN temperature and humidity sensor node 100 is installed in a constant humidity fog area to contact the air in order to compare the temperature and humidity data of the fog generation requirements to measure the air temperature and humidity data in the air and buried on the ground surface temperature As shown in FIG. 3, the temperature sensor and the humidity sensor 110 built therein to measure the temperature and humidity of the air and the ground temperature, and the temperature sensor and the humidity sensor 110 as shown in FIG. 3. An amplifier 121 for amplifying the measured analog temperature and humidity data, and a low pass filter 122 and the low pass filter for removing unrelated to signals such as noise in the analog data amplified by the amplifier 121. A sensor interface unit 120 including an A / D converter 123 for converting analog data filtered through 122 into digital data, and the sensor interface unit 120. USN communication module 130 for transmitting the temperature and humidity data converted into a digital signal through the USN network communication network to the data analysis unit 200 through wireless communication, and the USN communication module 130 to transmit data. The sensor node controller 140 to control and the power supply unit 150 for supplying a low power power using a battery to the USN temperature and humidity sensor node 100.

The data analyzer 200 which receives temperature and humidity data and atmospheric temperature data in the atmosphere of the constant fog region through the USN temperature and humidity sensor node 100 transmits temperature and humidity data through the USN network communication network. The receiving base node 210 and the temperature / humidity data transmitted through the base node 210 are compared with the fog generation requirement set by the user in the data comparator 220. The fog generation requirement is that the fog occurs when the difference between the air temperature and the ground temperature at a certain amount of humidity, the user presets the difference between the air temperature and the ground temperature and humidity of the fog occurs in the USN ON? The temperature and humidity data measured by the humidity sensor node 100 is compared by the data comparator 220, and the temperature and humidity data compared by the data comparator 220 is generated through the data processor 230. Determine if the requirements are met or not met. At this time, the data processor 230 instructs the mist elimination control unit 400 to operate the mist eliminating means 300 through the USN communication module 240 to the USN network communication network through the USN communication module 240 when the fog is generated. The means 300 is operated to remove the fog.

The mist removing means 300 is formed in the housing 310 is formed in a cylindrical shape so as to spray an aqueous solution mixed with the absorbent and water in a region where the fog occurs in a habitual manner, and formed at one end of the housing 310 to receive water pressure By spraying the nozzle outlet to finely spray the aqueous solution particles by the injection nozzle 320 to spray the fine aqueous solution particles, the water tank 330 for supplying the aqueous solution to the injection nozzle 320, and the housing The driving unit is formed on the other side of the 310 to generate a strong wind pressure through the rotation of the propeller to increase the injection distance of the aqueous solution particles sprayed through the injection nozzle 320 formed on one side to blow off the aqueous solution particles to the habitual mist generating area 340 and the power supply unit 350 for supplying power through the commercial power or a generator to the mist removing means 300. The principle of removing the mist by the mist removing means 300 is to control the outlet of the spray nozzle 320 to spray the fine aqueous solution particles to promote the generation of fine water droplets in the atmosphere before the sprayed aqueous solution particles generate fog In combination with the coagulum tuberculosis as hygroscopic microparticles, the weight of the coagulation tube is increased to free fall to remove the coagulation tube which causes fog in advance to prevent the generation of fog in advance, and also the aqueous solution particles sprayed after the fog generation In combination with the fog particles to free fall by increasing the weight of the fog particles can remove the fog itself, it is possible to reduce the humidity of the fog area by spraying the absorbent.

The fog removing means 300 is controlled by the fog removing control unit 400 and the fog removing control unit 400 measures temperature and humidity data measured by the USN temperature and humidity sensor node 100 in the data analyzing unit 200. When the fog meets the requirements for fog generation commands the fog removal control unit 400 to operate the fog removing means 300 through the USN network communication network and the fog removal control unit 400 commands the wireless communication through the USN network communication network Received to operate the mist elimination means 300. In this case, the fog removing control unit 400 is divided into an automatic mode and a manual mode. The automatic mode is to automatically operate the fog removing unit 300 through the command described above. Regardless of the command of 200), it can be operated manually.

Figure 4 is a view showing an embodiment of the present invention to install the USN temperature and humidity sensor node 100 in the street lamp to remove the fog on the road habitually fog and the USN temperature and humidity sensor node on the outer surface of the road Buried (100) to measure the temperature and humidity data in the air through the installed USN temperature and humidity sensor node 100, and measure the temperature data of the ground and transmit to the data analysis unit 200 through the USN network communication network The data analysis unit 200 compares the data received from the USN temperature and humidity sensor node 100 with the fog generation requirements, when the fog generation requirements are met, the fog removal means 300 installed on the roadside is a fog removal control unit 400 Ordered to spray the aqueous particles mixed with the absorbent and water on the road to remove the coagulation nucleus and the mist particles after the mist occurs before the mist occurs, It is configured to reduce the humidity of the fog area through.

The fog removing means 300 of the present invention can be installed in a mobile manner in the embodiment by spraying water particles against scattering dust or yellow sand generated in the construction site, quarry, manufacturing plants such as cement, yellow dust generating area, fine in the air The dust particles and the yellow dust particles may be combined with the sprayed water particles to freely remove and remove the dust particles and the yellow dust particles by increasing the weight of the dust particles and the yellow dust particles. Also, the spray nozzle 320 may be filled with ionized water and ozone water in the water tank 330. Can be used to deodorize ammonia, sterilize viruses such as swine flu, and remove bacteria, bacteria, and fungi.

In addition, the fog removing means 300 may be installed in a park or the like to spray water in the air to make the scenery of the park or the like to react with the sprayed water particles and sunlight to make a rainbow. It is possible to provide beautiful sights to those who visit the park, etc. Also, two fog removing means 300 are installed at both sides of the park or outdoor stage to spray water into the air through the spray nozzle 320 to form a water screen. This allows the image to shine through the laser light to illuminate the surroundings.In the existing water screen installation, the water fountain can be used to spray the water to solve the problem that can only be performed in the place where the fountain is installed. The fog removing unit 300 may be moved to perform image output using a water screen.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken in conjunction with the scope of the present invention. It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the scope of the present invention.

** Signs of the main parts of the drawings **
100: USN temperature and humidity sensor node 110: temperature sensor and humidity sensor
120: sensor interface 121: amplifier
122: Low Pass Filter 123: A / D Converter
130: USN communication module 140: sensor node control unit
150: power supply unit 200: data analysis unit
210: base node 220: data comparator
230: data processing unit 240: USN communication module
300: fog removing means 310: housing
320: spray nozzle 330: water tank
340: driving unit 350: power supply
400: fog removal control

Claims (6)

In the fog removal system using the USN to remove the fog by using an aqueous solution mixed with an absorbent and water in the area where the fog occurs regularly
It is installed in the area where fog occurs regularly, and it is buried in the air temperature, humidity, and ground surface through temperature sensor and humidity sensor to measure the temperature of the ground, and the weather information of the temperature and humidity at which the fog occurs is generated by the USN network communication network. Multiple USN temperature and humidity sensor nodes for measurement and transmission;
A data analyzer to determine whether fog is generated by receiving temperature and humidity data measured through the plurality of USN temperature and humidity sensor nodes through a USN network communication network and comparing the temperature and humidity requirements to generate fog;
The housing is formed in a cylindrical shape so as to spray the aqueous solution mixed with the absorbent and water in the region where the fog occurs in the habitual, and the nozzle is formed at one end of the housing to spray the aqueous particles to a fine size by water pressure A spray nozzle capable of adjusting the outlet size of the water, a water tank for supplying an aqueous solution to the spray nozzle, and a propeller to increase the spray distance of the aqueous solution particles formed on the other side of the housing and sprayed through the spray nozzle formed on one side. It is composed of a driving unit for generating a strong wind pressure through the rotation of the power supply unit for supplying power through the commercial power or generator to the mist removing means to remove the coagulation nuclei before the mist generation and the mist particles after the mist generation, Fog removing means for reducing humidity in a fog generating area;
When the temperature and humidity data measured by the USN temperature and humidity sensor node through the data analysis unit meets the fog generation requirements, by operating the fog removing means to remove the coagulation nuclei before the fog and the fog particles after the fog occurs, the fog by the absorbent A mist elimination control unit controlling the mist elimination means so as to reduce the humidity of a generation area; Fog removal system using the USN, characterized in that consisting of.
The method of claim 1,
The USN temperature and humidity sensor node includes a temperature sensor and a humidity sensor embedded in the sensor node to measure the temperature of the ground by embedding the temperature and humidity in the air in the area where the fog occurs in a habitual manner and the ground;
An amplifier for amplifying analog temperature and humidity data measured by the temperature sensor and a humidity sensor, a low pass filter for removing an unrelated signal such as noise to the analog data amplified by the amplifier, and the low pass A sensor interface unit including an A / D converter for converting analog data filtered through a filter into digital data;
A USN communication module configured to transmit temperature and humidity data converted into a digital signal through the sensor interface unit to a data analysis unit through wireless communication using a USN network communication network;
A sensor node controller for controlling data transmission through the USN communication module;
A power supply unit supplying low power power using a battery to the USN temperature and humidity sensor node; Fog removal system using the USN, characterized in that consisting of.
The method of claim 1,
The data analyzer may include: a base node configured to wirelessly transmit temperature and humidity data measured through a plurality of USN temperature and humidity sensor nodes through a USN network communication network;
A data comparison unit for comparing the temperature and humidity data transmitted from the base node with the temperature and humidity of the set fog generation requirement to determine whether the fog generation requirement is satisfied;
A data processing unit for sending a command to drive the fog removing unit to the fog removing control unit when the fog generation unit satisfies the fog generation requirement through the value determined by the data comparing unit;
A USN communication module for transmitting a command of the data processor to a fog removing control unit through a USN network communication network; Fog removal system using the USN, characterized in that consisting of.
delete The method of claim 1,
The mist removing means finely sprays the size of the aqueous solution particles by controlling the outlet of the injection nozzle, the sprayed aqueous solution particles are combined with the coagulation nuclei before the mist is generated, the weight of the coagulation nucleus is heavy, free fall to prevent the occurrence of fog After the mist is generated, the sprayed aqueous solution particles are combined with the mist particles, and the weight of the mist particles becomes heavy, thereby freezing the mist to remove the mist, and reducing the humidity of the mist generating region by using an absorbent. system.
The method of claim 1,
The mist elimination control unit transmits a command to operate the mist elimination means through the USN communication network through the USN communication module when the temperature and humidity data measured by the data analyzer through the USN temperature and humidity sensor node meets the fog generation requirement. And an automatic mode for automatically operating the fog control means and a manual mode for the user to selectively operate the fog control means.

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