KR102327296B1 - Inadication system indicating of air-condition data - Google Patents

Abstract

The present invention relates to an indication system outputting air quality information and, more specifically, to an indication system outputting air quality information which measures air quality of a certain space through a sensor and outputs measured air quality information and real-time measurement data of the meteorological administration. The indication system outputs information through a separately provided indicator and a user terminal.

Description

An indication system that outputs air quality information {INADICATION SYSTEM INDICATING OF AIR-CONDITION DATA}

The present invention relates to an indication system for outputting air quality information.

Specifically, the air quality of a specific space is measured through a sensor, and the measured air quality information and real-time measurement data of the Korea Meteorological Administration are output, but the output information is output through an indicator and a user terminal provided separately. It relates to an indication system.

Various gases, including oxygen, coexist in the atmosphere while generating, maintaining and disappearing. Due to the development of industry, gases harmful to living things are rapidly generated and leaked, which adversely affects the human body. It is possible to measure the air quality in the atmosphere by detecting the composition and distribution amount.

In general, an air quality measuring device measures the degree of contamination in the air in a building such as an office or warehouse, and displays the measured value on a display such as a monitor or interlocks ventilation or air conditioning systems to prevent indoor air discharge or outdoor air quality. It functions to maintain a comfortable indoor environment through inflow.

In other words, the main pollutants in indoor air are formaldehyde or volatile organic compounds (VOC) from building materials and furniture, carbon monoxide or sulfur dioxide from stoves and gas stoves, and microorganisms from humidifiers and carpets. There are substances, odors from food waste, and fine dust (PM10) from human activities.

Accordingly, recently, in order to display the pollution state in the air, as an example, an indoor air state display device is described in Korean Patent Application Laid-Open No. 10-2004-0013679.

The above technology is an indoor air quality display device applied to a residential space. The display unit 10 includes a temperature display unit 12, a humidity display unit 14, and an air quality display unit 16, and a speaker 20 that outputs a voice message. Consists of. In the above patent document, a display unit 10 for displaying each of temperature, humidity and air quality is provided so that the user can easily grasp the indoor air condition.

In addition, Korean Patent Publication No. 10-1532174 discloses an air quality notification device in which an air quality measuring device and a wireless terminal are interlocked and an air quality notification method thereof.

The above technology transmits the measured values measured by a gas meter that measures the types and concentrations of various gases maintained in the atmosphere to a wireless terminal and confirms them, but performs a situational response and notification function suitable for the measurement location and the public, so that the general public can easily recognize it The present invention relates to an air quality notification device in which an air quality measurement device and a wireless terminal are interlocked, and an air quality notification method therefor.

In addition, Patent Publication No. 10-2018-0116695 discloses an air quality notification device using a terminal.

In the above technology, when the measured value of air quality is measured above a set value, an air quality measuring device that notifies whether there is a danger through a speaker, a server that stores the measured value of the air quality measuring device, and the air quality measuring device or the server communicate and measure It consists of a terminal that displays a value, and when an air quality measurement value is received through the communication module of the terminal, an application stored in the user app unit is automatically executed to include a terminal control unit that displays the air quality measurement value on the terminal display unit. It is possible to share real-time accurate (second) fine dust measurement data through the measuring device installed in

In addition, Korean Patent Publication No. 10-2117838 describes an indoor air quality management type building automatic control system.

The technology acquires air quality parameters for each location in which the outdoor and indoor sensors are installed through an outdoor sensor and an indoor sensor at a preset period, and based on the acquired air quality parameter, the range of the space in the building where the air quality deterioration occurs. The air quality degradation area is a supply device that determines the air quality degradation area, increases the amount of air discharged per unit time of the air quality degradation area exhaust device, and supplies air to the air quality degradation area as an exhaust device for discharging the air from the air quality degradation area Increase the amount of air supply per unit time of the supply device, determine whether the air quality in the air quality degradation area has returned to a normal state through the outdoor sensor and the indoor sensor, and when the air quality in the air quality degradation area returns to a normal state The air discharge amount per unit time of the air quality reduction area discharging device is returned to the air discharge amount per unit time in a normal state, and the air supply amount per unit time of the air quality reduction area supply device is returned to the air supply amount per unit time in the normal state. It relates to an air quality management type building automatic control system.

Laid-Open Patent Publication No. 10-2004-0013679 Registered Patent Publication No. 10-1532174 Laid-open Patent Publication No. 10-2018-0116695 Registered Patent Publication No. 10-2117838

An object of the present invention is to measure the air quality of a specific space through a sensor and output the measured air quality information and real-time measurement data of the Meteorological Agency, but the output information is output through an indicator and a user terminal provided separately, air quality information It is to provide an indication system that outputs.

An indication system for outputting air quality information according to the present invention, which has been devised to achieve the above object, includes: a sensor provided in a measurement space; a server for receiving information from the sensor, analyzing and calculating information to be output; Including; a user terminal and an indicator for outputting the information of the server;

The server includes: a receiver for receiving measurement information from a sensor; an interlocking unit for receiving real-time information by interworking with the Meteorological Administration server; an analysis unit for performing each analysis based on the information received from the receiving unit and the interworking unit; a calculation unit for calculating a final calculated value based on the result of the analysis unit; and an output unit for outputting the information of the calculation unit through an indicator or a user terminal.

At this time, the sensor includes a carbon dioxide measurement sensor for measuring carbon dioxide (Co2); an oxygen sensor for measuring oxygen (O2) concentration; It is characterized in that it is composed of a sensor group including; TVOC measuring sensor for total volatile organic compounds (TVOC) measurement.

In addition, the analysis unit,

The SP score is analyzed by dividing the fine dust information received from the Meteorological Agency server into a 5-point scale of 0 points, 40 points, 60 points, 80 points, and 100 points,

It is characterized in that the fine dust information based on the average is set as 60 points, and the SP score is analyzed by analyzing whether 20% or 50% is high or low with respect to the above criteria.

In addition, the analysis unit,

Based on the temperature and humidity information received from the Meteorological Agency server, DI information is calculated by the following equation, and based on the calculated DI information, it is divided into a 5-point scale of 0 points, 40 points, 50 points, 80 points, and 100 points. Analyze the CP score,

It is characterized in that the DI information is classified on a 5-point scale in the order from less than 21 to more than 29.

[Equation]

DI(℃) = T _a -0.55 * (1-0.01 * RH) * (T _a -14.5)

In addition, the analysis unit,

The oxygen information received from the sensor is analyzed as 0 points at 20-23% of the measured values, 80 points at the measured values exceeding 23%, and 0 points at the measured values below 19%, and the OP score is analyzed,

Analyze the TVOC information received from the sensor as 100 points at a measurement value of less than 100 ppb, 80 points in a measurement value of 100 to 500 ppb, and 0 points in a measurement value exceeding 500 ppb,

The carbon dioxide information received from the sensor is 100 points at a measured value of less than 400 ppm, 80 points at a measured value of 401 to 700 ppm, 50 points at a measured value of 701 to 1,000 ppm, 40 points at a measured value of 1,001 to 3,000 ppm, and It is characterized in that the COP score is analyzed as 0 points at the measured values exceeding 3,000 ppm.

In addition, the calculation unit,

Based on the SP score, CP score, OP score, VP score, and COP score analyzed in the analysis unit, the final score (IAR) is calculated based on the following equation,

Text based on the calculated final score,

The output unit is characterized in that it controls to output the information characterized by the calculation unit.

[Equation]

Final score (IAR) = ((2*SP) + CP + OP + VP + COP) / 2

According to the indication system for outputting air quality information according to the present invention, the air quality of a specific space is measured through a sensor and the measured air quality information and real-time measurement data of the Korea Meteorological Administration are output, but the output information is separately provided with an indicator and a user terminal. There is an advantage of being able to provide an indication technology for outputting through .

1 shows an indication system for outputting air quality information according to the present invention.
2 shows a server of an indication system for outputting air quality information according to the present invention.

The terms or words used in the present specification and claims should not be construed as being limited to their ordinary or dictionary meanings, and the inventor may properly define the concepts of the terms to best describe his invention. Based on the principle, it should be interpreted as meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention and do not represent all the technical spirit of the present invention, so various equivalents that can be substituted for them at the time of the present application It should be understood that there may be variations and examples.

Hereinafter, prior to the description with reference to the drawings, it is not shown or specifically described for the known configurations that are not necessary to reveal the gist of the present invention, that is, those skilled in the art that can be added obviously by those skilled in the art. reveal the sound

The present invention relates to an indication system for outputting air quality information.

Specifically, the air quality of a specific space is measured through a sensor, and the measured air quality information and real-time measurement data of the Korea Meteorological Administration are output, but the output information is output through an indicator and a user terminal provided separately. It relates to an indication system.

An indication system for outputting air quality information according to the present invention will be described with reference to the accompanying drawings.

1 shows an indication system for outputting air quality information according to the present invention, and FIG. 2 shows a server of the indication system for outputting air quality information according to the present invention.

The present invention according to the accompanying drawings is a sensor provided in a measurement space; a server for receiving information from the sensor, analyzing and calculating information to be output; It includes; a user terminal and an indicator for outputting the information of the server.

In this case, the server may be connected to the Meteorological Agency server to receive weather information provided by the Meteorological Agency in real time.

Such a server will be described with reference to FIG. 2 of the accompanying drawings.

Prior to that, the sensor includes a carbon dioxide measurement sensor for measuring carbon dioxide (Co2); an oxygen sensor for measuring oxygen (O2) concentration; TVOC measurement sensor for total volatile organic compounds (TVOC) measurement; consists of a sensor group including.

That is, the sensor provided in the measurement space to measure the air quality of any one indoor means a sensor group including the above sensors.

In addition, as information received in real time in connection with the Meteorological Administration server, fine dust information and temperature and humidity information are received.

Referring to FIG. 2 , the server includes: a receiving unit for receiving measurement information from a sensor; an interlocking unit for receiving real-time information by interworking with the Meteorological Administration server; an analysis unit for performing each analysis based on the information received from the receiving unit and the interworking unit; a calculation unit for calculating a final calculated value based on the result of the analysis unit; and an output unit for outputting the information of the calculation unit through an indicator or a user terminal.

If output is performed through a user terminal, the output unit may output information through App or Web.

Analysis through the analysis unit will be described through the tables below.

First, the fine dust information received from the Meteorological Agency server is analyzed based on [Table 1] to provide an analysis value.

fine dust SP score 50% lower than baseline 100 20% lower than baseline 80 standard 60 20% higher than standard 40 50% higher than standard 0

That is, as a 5-point scale, scores are divided into 0 points, 40 points, 60 points, 80 points, and 100 points, but the fine dust information based on the average is 60 points, and 20% or 50% of the above criteria is Analyze whether it is high or low, and analyze it with an SP score.

In addition, the temperature and humidity information received from the Meteorological Agency server is analyzed based on [Table 2].

DI information Normal discomfort according to temperature CP score < 21℃ comfort 100 21 ~ 24℃ More than 50% comfortable 80 25 ~ 27℃ Less than 50% comfortable 50 28 ~ 29℃ to the extent that most people are unpleasant 40 > 29℃ to the extent that everyone is unpleasant 0

That is, as shown in [Table 2], DI information is calculated based on the temperature and humidity information received from the Meteorological Administration server, and based on the calculated DI information, ordinary people classify the degree of discomfort, and each is 100 on a 5-point scale. , 80, 50, 40 are classified as 0 points and analyzed.

In this case, DI information may be calculated through Equation 1 below.

[Equation 1]

DI(℃) = T _a -0.55 * (1-0.01 * RH) * (T _a -14.5)

Here, T _a is temperature information measured from the Meteorological Administration server, a is an index value, and RH means humidity information.

In addition, the oxygen information received through the sensor is analyzed based on [Table 3].

oxygen readings OP score 20 to 23% 100 > 23% 80 < 19% 0

In addition, TVOC information is analyzed based on [Table 4].

TVOC measurements VP score < 100ppb 100 100 to 500ppb 80 > 500ppb 0

Finally, carbon dioxide information is analyzed based on [Table 5].

carbon dioxide measurement COP score < 400ppm 100 401 ~ 700ppm 80 701 ~ 1,000ppm 50 1,001 ~ 3,000ppm 40 > 3,000ppm 0

Based on the SP score, CP score, OP score, VP score, and COP score calculated through [Table 1] to [Table 5], the calculation unit calculates the final score by averaging as in Equation 2 above.

[Equation 2]

Final score (IAR) = ((2*SP) + CP + OP + VP + COP) / 2

Based on the final score calculated in this way, the calculator performs characterization for output as shown in [Table 6].

final score message 90 to 100 5★ 80 to 89 4★ 70 to 79 3★ 50 to 69 2★ < 50 1★

At this time, even if the characterization does not necessarily use ★, any delimiter character that people can understand can be used.

In addition, the output unit transmits the characterized text as output information through the calculation unit so that it can be output through an indicator or a user terminal.

Meanwhile, although it is sufficient for the user terminal to output air quality information in the space where the user is located, the indicator may output air quality information of all managed spaces according to design conditions.

To this end, the indicator may include a plurality of divided output screens.

Also, as another example, a camera (CAM) device may be further included in front of the indicator, and the camera device may be connected to the indicator with a separate bracket so that the shooting direction is directed toward the screen of the indicator.

However, it is desirable for users to prevent the camera device from interfering with the output information of the indicator, and for this purpose, the bracket connecting the camera device to the indicator can be configured to be adjustable in length by an antenna method.

In addition, the indicator includes a receiving module for receiving information of the camera device; a failure determination module for judging that a broken screen exists among a plurality of screens of the indicator; A control unit including; a sequence change control module for controlling the information to be output on the screen on which the failure is determined by the failure determination module is outputted to the next screen, and the information output on the screen after the failed screen is delayed based on the order may include.

The failure determination module performs a pixel analysis based on the image of the camera device, thereby judging a failure on a screen without output of information.

In addition, the order change control module, for example, when it is assumed that the screens 1, 2, 3, and 4 exist in the indicator, the control unit can identify the order of the screens, and if screen 2 When a failure is determined, the output information to be outputted in No.2 is outputted in No.3, and the output information to be outputted to the screen No.3 is outputted in No.4 because the order is disregarded.

However, the output information that is not output due to the order being pushed is continuously output on the first screen. That is, in the above case, the output information to be originally output on the 4th screen is output through the alternating output of the output information on the 1st screen. This can be done through the order change control module.

In this case, the output information may include identification information of the sensor together with information calculated by the calculation unit, and the identification information of the sensor is output as identification information of the measurement space when it is output on the screen. For example, it is output as <Room 2 '5★'>.

Therefore, even if a failure occurs in any one screen, the user can receive the measured values properly without confusion of the measured values.

What has been described using the accompanying drawings in the above is to describe only the main points of the present invention, and as much as various designs are possible within the technical scope, it is obvious that it is not limited to the configuration of the accompanying drawings of the present invention.

Claims (6)

a sensor provided in the measurement space;
a server for receiving information from the sensor, analyzing and calculating information to be output;
Including; a user terminal and an indicator for outputting the information of the server;
The server is
a receiver for receiving measurement information from the sensor;
an interlocking unit for receiving real-time information by interworking with the Meteorological Administration server;
an analysis unit for performing each analysis based on the information received from the receiving unit and the interworking unit;
a calculation unit for calculating a final calculated value based on the result of the analysis unit;
and an output unit for outputting the information of the calculation unit through an indicator or a user terminal; and
The analysis unit,
The SP score is analyzed by dividing the fine dust information received from the Meteorological Agency server into a 5-point scale of 0 points, 40 points, 60 points, 80 points, and 100 points,
An indication system for outputting air quality information, characterized in that the fine dust information based on the average is 60 points, and the SP score is analyzed by analyzing whether 20% or 50% is high or low with respect to the standard.
The method according to claim 1,
The sensor includes a carbon dioxide measurement sensor for measuring carbon dioxide (Co2); an oxygen sensor for measuring oxygen (O2) concentration; An indication system for outputting air quality information, characterized in that it consists of a sensor group including; a TVOC measurement sensor for total volatile organic compounds (TVOC) measurement.
delete The method according to claim 1,
The analysis unit,
Based on the temperature and humidity information received from the Meteorological Agency server, DI information is calculated by the following equation, and based on the calculated DI information, it is divided into a 5-point scale of 0 points, 40 points, 50 points, 80 points, and 100 points. Analyze the CP score,
An indication system for outputting air quality information, characterized in that the DI information is classified on a 5-point scale in the order from less than 21 to exceeding 29.
[Equation]
DI(℃) = T _a -0.55 * (1-0.01 * RH) * (T _a -14.5)
(Here, T _a is temperature information measured from the Meteorological Agency server, a is an index value, and RH means humidity information)
5. The method according to claim 4,
The analysis unit,
The oxygen information received from the sensor is analyzed as 0 points at 20-23% of the measured values, 80 points at the measured values exceeding 23%, and 0 points at the measured values below 19%, and the OP score is analyzed,
Analyze the TVOC information received from the sensor as 100 points at a measurement value of less than 100 ppb, 80 points in a measurement value of 100 to 500 ppb, and 0 points in a measurement value exceeding 500 ppb,
The carbon dioxide information received from the sensor is 100 points at a measured value of less than 400 ppm, 80 points at a measured value of 401 to 700 ppm, 50 points at a measured value of 701 to 1,000 ppm, 40 points at a measured value of 1,001 to 3,000 ppm, and An indication system for outputting air quality information, characterized in that the COP score is analyzed as 0 in the measured value exceeding 3,000 ppm.
6. The method of claim 5,
The calculation unit,
Based on the SP score, CP score, OP score, VP score, and COP score analyzed in the analysis unit, the final score (IAR) is calculated based on the following equation,
Text based on the calculated final score,
An indication system for outputting air quality information, characterized in that the output unit controls to output the textualized information by the calculation unit.
[Equation]
Final score (IAR) = ((2*SP) + CP + OP + VP + COP) / 2

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