KR101529549B1 - System for providing forest bathing air quality health index - Google Patents

Abstract

The present invention relates to a system for providing a forest bathing air quality health index capable of detecting the concentration of phytoncide in the atmospheric environment of a forest, and providing the concentration by indexing the same per area. The system comprises: multiple detecting modules (100) distributed and arranged per a forest area, detecting the concentration for a terpene derivative in the atmospheric environment, and enabling to output detected data outside; a DB server (210) for quantifying an associative relation of a disease for the terpene derivative, and storing disease information; a control server (220) for receiving the detected data outputted from the detecting modules (100), and storing the detected data along with location information of each detecting module (100) in a database (DB); and an index calculation server (230) for indexing the associative relation between the detected terpene derivative and a meteorological factor or the disease based on each area, and calculating index information per area.

Description

A system for providing a forest air quality health index is provided.

The present invention relates to a system for providing a forest bath air quality index, and more particularly, to a system capable of detecting the concentration of phytoncide in the atmospheric environment of a forest and indexing the detected concentration.

Phytoncide refers to all of the materials that are produced by the plants in the forest and has bactericidal properties. Phytoncide also stimulates peripheral blood vessels and enhances cardiopulmonary function in addition to psychological stability. Bronchial asthma, treatment of pulmonary tuberculosis, and also helps strengthen the heart, is also known to have a pharmacological action to disinfect the skin.

The main component of phytoncide is terpene, which creates a fragrant smell in the woods.

Terpenes are flammable unsaturated hydrocarbons widely distributed in plants and animals. They are generic names of carbohydrates having the general formula (C ₅ H ₈ ) _n (n 2) and derivatives thereof, and the number of isoprene (C ₅ H ₈ ) . (C ₁₀ H ₁₆ ), three sesquiterpenes (C ₁₅ H ₂₄ ), four diterpenes (C ₂₀ H ₃₂ ), six triterpenes (C ₃₀ H ₄₈ ) Terpene (C ₄₀ H ₆₄ ) has eight isoprene units each.

The terpene ingredient in pine leaves is mostly monoterpene, which is highly volatile and harmless to most human beings as a subject of forest bathing. For example, alpha-pinene is known to give a psychological sense of stability and is known to stabilize depressed or anxious states psychologically.

As described above, the terpene derivatives have various kinds and exhibit different effects depending on the components thereof, and various studies have been conducted on them.

In addition, recently, as interest in health has increased, the number of people who want to enjoy forest bathing from the polluted environment is increasing, and thus terpenes that are generated in forests are attracting attention.

However, those who seek the mountains for forest baths are aware of the goodness of the forests, but they do not get detailed health information such as how much exposure to phytoncide concentration can maximize the effects of forest bathing.

For example, the phytoncide concentration, which is advantageous to forest bathing, changes with season and environmental conditions such as temperature and humidity, and also varies with time.

In addition, depending on the disease, the constituents of the effective phytoncide also vary.

Therefore, in order to achieve effective forest bathing, it is urgently required to provide accurate information.

Japanese Patent Application Laid-Open No. 10-2011-0088235 (published on March 31, 2013)

It is an object of the present invention to provide a system capable of automatically monitoring the phytoncide concentration by forest area and indexing the phytoncide concentration by region to provide effective information to the forest bath for each disease.

The present invention also provides a detection module for automatically monitoring the phytoncide concentration, which is installed in a forest area, and can stably supply the standard gas required for calibration in order to accurately detect a target sample, And to provide a system in which means can be provided.

In order to accomplish the above object, a system for providing a forest bath air health index according to the present invention comprises: a plurality of detection modules which are distributed and arranged in forest areas to detect concentrations of terpene derivatives in an atmospheric environment and send out detection data to the outside; A DB server for storing disease information by quantifying a relation of diseases to terpene derivatives; A management server receiving the detection data transmitted from the detection module and storing the detected data together with the position information of each detection module in a database; And an exponent calculation server that exponents the relationship between the terpene derivative and the meteorological factor or disease detected according to each region to calculate regional index information.

Preferably, the present invention further includes an index information providing server for providing the regional health index information calculated by the index calculating server in the form of a map.

Preferably, in the present invention, the detection module further comprises a standard gas generator for generating a standard gas for data calibration.

More preferably, in the present invention, the standard gas generator comprises: a zero air generator; A storage container in which a high purity liquid terpene is stored; A generating chamber in which the storage container is hermetically sealed with the outside; A Peltier element for controlling the temperature inside the generation chamber; A mixing chamber for mixing the generated gas generated in the generation chamber with the zero air delivered from the zero air generator, and transferring the mixed gas to the analysis unit; A first flow rate adjusting unit provided between the zero air generator and the generation chamber to adjust a flow rate of the gas; A second flow regulator provided between the generation chamber and the mixing chamber for regulating the flow rate of the gas; And a controller which is controlled by the management server to control the temperature by supplying power necessary for driving the Peltier element and to control the supply flow rate of the first flow rate regulator or the second flow rate regulator.

More preferably, in the present invention, the storage container further comprises a remaining amount detecting unit capable of detecting the remaining amount of the stored liquid terpenes, wherein the detection signal of the remaining amount detecting unit is transmitted to the management server by the controller .

The system of providing the forest air quality health index according to the present invention automatically monitors the phytoncide concentration for each forest area and indexes the phytoncide concentration according to each region to provide a forest air quality health index, thereby providing more effective forest bath information. Health index information can be provided.

In addition, the system according to the present invention is a detection module installed in a forest area for automatically monitoring phytoncide concentration, and can stably supply standard gas required for calibration in order to accurately detect a target sample, So that it is possible to efficiently manage it.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an overall configuration diagram of a system for providing a forest bath air quality index according to the present invention;
FIG. 2 is a diagram illustrating an example of a disease information table stored in a DB server in the system according to the present invention;
3 is a diagram illustrating an example of a regional health index table calculated by the index calculation server in the system according to the present invention,
4 is a diagram illustrating an output format of the exponent information provided by the exponent information providing server in the system according to the present invention,
5 is a block diagram showing a preferred embodiment of a detection module in a system according to the present invention;
6 is a configuration diagram showing a preferred embodiment of the standard gas generator in the detection module according to the present invention.

The specific structure or functional description presented in the embodiment of the present invention is merely illustrative for the purpose of illustrating an embodiment according to the concept of the present invention, and embodiments according to the concept of the present invention can be implemented in various forms. And should not be construed as limited to the embodiments described herein, but should be understood to include all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

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

FIG. 1 is an overall configuration diagram of a system for providing a forest bath air quality index according to the present invention.

Referring to FIG. 1, a system according to the present invention includes a plurality of detection modules 100 dispersedly disposed in forest areas to detect concentrations of terpene derivatives in an atmospheric environment and to send detection data to the outside; A database server (210) for storing disease information by quantifying a relation of diseases to terpene derivatives; A management server 220 receiving detection data sent from the detection module 100 and storing detection data in the database together with the position information of each detection module 100; And an exponent calculation server 230 for exponentially calculating a correlation between the terpene derivative and the disease detected according to each region.

The detection module 100 detects the terpene derivatives constituting the phytoncide and detects the concentrations of the terpene derivatives and outputs the detected concentrations to the management server 220. [ As shown in Fig.

DB server 210 stores the disease information by quantifying the relation of the disease to the terpene derivative, and the quantified disease information can be updated to reflect the new research result of the disease on the terpene derivative.

FIG. 2 is a view illustrating an example of a disease information table stored in the DB server in the system according to the present invention.

Referring to FIG. 2, the DB server quantifies and stores related diseases and correlations with terpene derivatives. For example, in the present embodiment, the DB server quantifies and stores related diseases and related correlations with terpene derivatives such as alpha-pinene, beta-pinene, d-limonene, Correlations of each disease are preserved, indicating a high therapeutic effect between the highly correlated terpene derivatives and the disease.

Such a disease information table can be updated by reflecting a new study result of a disease of a terpene derivative, and can be performed through a management server.

1, the management server 220 receives the detection data transmitted from the detection module 100 and transmits detection data (detection concentration of the terpene derivative) to the database (not shown) together with the position information of each detection module 100 DB).

On the other hand, the detection module 100 periodically detects the terpene derivatives at predetermined time intervals and transmits detection data to the management server 220. Alternatively, the detection module 100 may transmit detection data to the detection module 100 according to the detection instruction signal, The transmission of the detection data can be performed.

In this embodiment, the detection module 100 and the management server 220 exemplify transmission of data by wireless communication, but it can be understood that data can be transmitted by wireless communication.

The exponent calculation server 230 exponentially calculates the correlation between the terpene derivative and other factors detected according to each region.

The index calculated by the index calculation server 230 can be calculated as a meteorological factor such as temperature, relative humidity, or a function of each disease.

For example, it is possible to calculate and provide an air quality index including terpene derivative concentration, meteorological factor, representative reference substance concentration in the ambient air, and the like, Means for directly receiving the weather factor data detected from each detection module or receiving the weather factor information of the corresponding region from the server storing other weather related data and calculating the air quality index.

Air quality index = f _area (Terpene derivative concentration; meteorological factor; environmental standard substance concentration)

As another example, the exponent calculation server 230 may calculate the association of the terpene derivative concentration and the disease detected according to each region with the air quality health index.

Health index = f _area (Terpene derivative concentration; disease)

3 is a diagram illustrating an example of a regional health index table calculated by the index calculation server in the system according to the present invention.

Referring to FIG. 3, the health index is calculated for each terpene derivative concentration and related disease detected in each region, and stored in a table.

Although not shown, the exponent calculation server 230 may be provided with a separate database, and the calculated exponent may be stored for each period and for each time period together with the detection time information of the detection module 100.

Meanwhile, the regional health index information calculated by the index calculation server 230 may be provided in the form of a map by the health index index information providing server 240.

The user can access the index information providing server 240 using the terminal device 1 to check the health index for each region, and in particular, can select a specific disease and search for a more effective region for the disease.

4 is a diagram illustrating an output format of the exponent information provided by the exponent information providing server in the system according to the present invention.

Referring to FIG. 4, a user can check various index information from an index information providing server through an app installed in the smartphone 10.

For example, an app installed in the smartphone 10 provides a menu 11 for various diseases. When a user selects a disease of interest, a health index is displayed on a face chart 12), and in addition, the health index can be output in numerical form (12). Therefore, the user can check the health index of each region and find out the region favorable to the disease of interest.

In addition, the system of the present invention may be provided with a geographical information providing server. When a user selects an area of interest by interfacing with a location information service of a smart phone, the geographical information providing server transmits route information To the user through the app.

On the other hand, the index calculation server 230 calculates the average value and the variation range of the health index by season and time by database-managing the history information about the health index of each region, It is possible to provide predicted information by estimating the health index for each region.

Meanwhile, in the system of the present invention, the detection module is dispersedly disposed according to the forest area to detect terpene derivatives of the atmospheric environment, and therefore periodic calibration work of the detection module is required to increase the reliability of detection data.

Therefore, the present invention is characterized in that a standard gas required for a calibration operation is stably supplied at the installation site, thereby providing a means for efficiently performing a calibration operation.

5 is a configuration diagram showing a preferred embodiment of the detection module in the system according to the present invention.

Referring to FIG. 5, the detection module according to the present embodiment includes an analysis unit 110 for detecting terpenes in the atmospheric environment and detecting concentration of the terpenes; A standard gas generator (not shown) for supplying a standard gas generated by vaporizing a liquid terpene standard material to the analyzer 110 in accordance with a control signal of the management server 220 in order to calibrate the concentration detected by the analyzer 110 120).

The analysis unit 110 detects terpenes, especially monoterpenes (alpha-pinene, beta-pinene, d-limonene, etc.), which are the main substances of phytoncide for monitoring phytoncide in the atmospheric environment, (Gas Chromatography / Mass Spectrometry) (111).

It is preferable that the analysis unit 110 is provided with means for removing various contaminants such as a gas sample remaining in the interior of the analyzer 110 so that the analyzer 110 can be operated independently for a long period of time. For example, Japanese Patent Application Laid-Open No. 10-0545455 (Registered on January 17, 2006) can be used.

The analysis unit 110 may further include a thermal desorber 112 and the thermal desorber 112 may be used for calibrating the detected data using the standard gas supplied from the standard gas generator 120 .

The heat desorber 112 desorbs the standard gas generated in the standard gas generator 120 and adsorbed to the adsorption trap, and the desorbed standard gas is measured by the gas chromatograph mass analyzer 111 and data calibration is performed .

The standard gas generator 120 generates a standard gas required for a calibration operation and supplies the generated standard gas to the analyzer 110 to calibrate the detected concentration. The specific description thereof will be described with reference to the related drawings.

The detection module 100 may further include an interface unit 130 for transmitting and receiving data to and from the management server 220.

The management server 220 remotely controls the operation of the analyzer 110 and the standard gas generator 120 and operates the standard gas generator 120 every predetermined period (for example, every three months) A calibration operation can be performed on the wafer 110.

6 is a configuration diagram showing a preferred embodiment of the standard gas generator in the detection module according to the present invention.

6, the standard gas generator 120 includes a zero air generator 121, a storage vessel 122 for storing a high purity liquid terpene, and a storage vessel 122 that is hermetically sealed to the outside The Peltier element 124 for controlling the temperature inside the generation chamber 123 and the zero generated by the zero air generator 121 together with the gas generated in the generation chamber 123, A mixing chamber 125 for mixing standard gas with the air and delivering the standard gas to the analysis unit 110 and a first flow rate adjusting unit 120 provided between the zero air generator 121 and the generation chamber 123 for controlling the flow rate of the gas, A second flow control unit 127 provided between the generation chamber 123 and the mixing chamber 125 to control the flow rate of the gas and a control server 220, The first flow rate regulator 126 regulates the temperature by supplying power necessary for driving the device 124, And a controller 128 for controlling the supply flow rate of the second flow rate regulator 127.

The zero air generator 121 generates pure air to supply zero air to the generating chamber 123. For example, the zero air generator 121 introduces outside air using a vacuum pump, Air can be supplied.

The storage vessel 122 may be provided by a vial and stores terpenes, preferably monoterpenes (alpha-pinene, beta-pinene, d-limonene, etc.) as standard solutions in high purity liquid phase.

The generating chamber 123 may be provided by being coated with an inert material such as glass or Teflon inside the body of the stainless steel in which the storage container 122 is stored in an airtight manner with the outside.

Preferably, the storage container 122 may further include a remaining amount detecting unit 129 capable of detecting the remaining amount of the stored reference material, and the residual amount data of the reference material detected by the remaining amount detecting unit 129 may be stored in the controller 128 To the management server 220 to inform the storage container 122 of the replenishment or replacement timing of the reference material.

For example, the remaining amount detecting unit 129 may measure the weight of the reference material, and the residual amount detection may be made.

The generation chamber 123 is connected to the side of the zero air generator 121 so that the zero air generated by the zero air generator 121 can be supplied and the mixing chamber 125 is connected to the upper end of the generation chamber 123, The vaporized gas may be diffused into the mixing chamber 125.

A Peltier element 124 is provided on the outer circumferential surface of the generation chamber 123 to control the temperature inside the generation chamber 123. The Peltier element 124 is cooled or heated inside the generating chamber 123 by the applied electromotive force.

The generating chamber 123 may be provided with a hot wire HC1 separate from the Peltier element 124 and the power supply is controlled by the controller 128 to maintain the generating chamber 123 at a predetermined temperature .

The mixing chamber 125 is mixed with the generated gas generated in the generating chamber 123 and the zero air transferred from the zero air generator 121. The standard gas thus generated in the mixing chamber 125 is analyzed And the analysis is performed and used for calibration.

The hot wire HC2 may be wound around the outer circumferential surface of the mixing chamber 125 and the power supply to the hot wire HC2 may be controlled by the controller 128 to maintain the mixing chamber 125 at a predetermined temperature .

The first flow rate regulator 126 is provided between the zero air generator 121 and the generation chamber 123 to adjust the gas flow rate.

The second flow rate regulator 127 is provided between the generation chamber 123 and the mixing chamber 125 to adjust the flow rate of the standard gas.

A known mass flow controller may be used for the accurate flow control of the first and second flow rate regulators 126 and 127 and the accurate flow rate control may be performed according to the control signal transmitted from the controller 128 .

The controller 128 controls the internal temperature of the generation chamber 123 by supplying power necessary for driving the Peltier element 124. The controller 128 controls the supply flow rate of the first flow rate regulator 126 or the second flow rate regulator 127 .

Meanwhile, the controller 128 can be controlled by the management server 220.

In the present invention, the transfer line through which the gas flows may be provided by a glass tube, and a hot line (HC3) may be provided along the transfer line to maintain the temperature of the transfer gas at a constant level.

The detection module according to the present invention thus constructed is installed in a site where monitoring of phytoncide is required, and the detection concentration of the terpene derivative formed in the detection module 100 is transmitted to the management server 220.

Meanwhile, the management server 220 periodically or arbitrarily performs a calibration operation for the detection module 100.

More specifically, when the management server 220 transmits a calibration work command to the detection module 100, the controller 128 supplies power to the Peltier element 124 to raise the internal temperature of the generation chamber 123, The liquid standard solution (mono terpene) in the vessel 122 is vaporized and the zero air generated in the zero air generator 121 is supplied to the generation chamber 123 and diffused into the mixing chamber 125 together with the vaporized gas And transmitted to the analysis unit 110.

Meanwhile, the controller 128 controls the second flow rate controller 127 to adjust the flow rate of the standard gas delivered from the generation chamber 123 to the mixing chamber 125 so that the concentration of the standard gas delivered to the analyzer 110 Can be accurately adjusted.

In the process of supplying the standard gas to the analysis unit 110, the controller 128 controls the temperature inside the generation chamber 123 or adjusts the temperature of the first gas flow rate regulator 126 and the second flow rate regulator 126, The controller 128 can supply power to each of the heating wires HC1 and HC2 to prevent the temperature of the standard gas from being changed during the movement of the standard gas, The temperature can be maintained at a certain level.

When the calibration operation is completed, the controller 128 controls the power applied to the Peltier element 124 so that the inside of the generation chamber 123 is kept at a predetermined temperature or lower, so that the standard material stored in the storage container 122 is maintained in the liquid state .

After the calibration operation is completed, the standard liquid can be maintained in a liquid state and stably stored for a long period of time in a stable manner.

On the other hand, the manager checks the remaining amount of standard material delivered to the management server 220 by the remaining amount detecting unit 129 and stores the same in the detection module 100 Standard solution can be maintained.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventions. It will be apparent to those of ordinary skill in the art.

100: Detection module 110:
120: Standard gas generator 121: Zero air generator
122: storage container 123: generating chamber
124: Peltier element 125: Mixing chamber
126: first flow rate regulator 127: second flow rate regulator
128: Controller 129:
130: Interface 210: DB server
220: management server 230: exponent calculation server
240: Index information providing server

Claims (6)

A plurality of detection modules which are distributed and arranged by forest areas and detect the concentration of the terpene derivatives in the atmospheric environment to send detection data to the outside;
A DB server for storing disease information by quantifying a relation of diseases to terpene derivatives;
A management server receiving the detection data transmitted from the detection module and storing the detected data together with the position information of each detection module in a database;
And an exponent calculation server for exponentially indexing the relationship between the terpene derivative and the meteorological factor or disease detected in each region to calculate regional index information. The system for providing a forest air quality health index according to claim 1, further comprising: an exponent information providing server for providing the map information of the region-specific index information calculated by the index calculating server. The apparatus of claim 1,
An analysis unit for detecting the concentration of terpene in the atmospheric environment;
And a standard gas generator for generating a standard gas for data calibration with respect to the concentration detected by the analyzer. The method of claim 3,
Wherein the standard gas generator comprises:
A zero air generator;
A storage container in which a high purity liquid terpene is stored;
A generating chamber in which the storage container is hermetically sealed with the outside;
A Peltier element for controlling the temperature inside the generation chamber;
A mixing chamber for mixing the generated gas generated in the generation chamber with the zero air delivered from the zero air generator, and transferring the mixed gas to the analysis unit;
A first flow rate adjusting unit provided between the zero air generator and the generation chamber to adjust a flow rate of the gas;
A second flow regulator provided between the generation chamber and the mixing chamber for regulating the flow rate of the gas;
And a controller for controlling the supply flow rate of the first flow rate adjusting unit or the second flow rate adjusting unit by controlling the temperature by supplying power necessary for driving the Peltier element by the control server, Health Index System. The system for providing a forest air quality health index according to claim 4, wherein the storage container further comprises a remaining amount detecting unit capable of detecting the remaining amount of the stored liquid terpenes. 6. The system for providing a forest bath air health index according to claim 5, wherein the detection signal of the remaining amount detecting unit is transmitted to a management server by a controller.

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