KR100577213B1 - Method for Controlling Airflow Volume of Ventilating System - Google Patents

Abstract

The present invention relates to a method for controlling the air volume of a ventilation system to improve the efficiency of air cleaning by controlling the air volume of the fan in response to the relative measured value of the VOC (volatile organic compound) concentration and the rapid change of the VOC concentration during air cleaning. Reading the VOC initial value V _O and the current VOC concentration value V _New ; Obtaining a relative VOC concentration value V _New -V _O and a VOC concentration change amount V _New -V _Old using the initial VOC value V _O and the current VOC concentration value V _New ; Determining a level of the VOC concentration by comparing a reference level preset in a plurality of steps with the relative VOC concentration value V _New -V _O ; Determining a level of the VOC concentration change amount by comparing the reference level preset in a plurality of steps with the VOC concentration change amount (V _New -V _Old ); And controlling the driving intensity of the air supply fan and the exhaust fan according to the determined level of the VOC concentration and the level of the VOC concentration change amount. Therefore, the present invention determines the degree of pollution of the indoor air through the relative measurement value of VOC concentration and the amount of VOC concentration change, and controls the air volume of the ventilation system according to the determined degree of pollution to improve the efficiency of air cleaning with the most suitable type of air volume. It can be maximized.

Air Conditioning / Ventilation System / Air Flow / VOC (Organic Compound)

Description

Method for Controlling Airflow Volume of Ventilating System

1 is a view showing the overall configuration of a general air conditioner consisting of an air conditioner and a ventilation system

2 is a block diagram showing the configuration of an air conditioner centered on a ventilation system;

3 is a flowchart illustrating a method for controlling air volume during air cleaning according to the prior art;

4, 5a to 5e is a flow chart showing a method for controlling the air volume during air cleaning through the ventilation system of the present invention

* Explanation of symbols for main parts of the drawings

31: control unit 34: remote control

35: indoor unit 36: damper position detection sensor

37: VOC sensor 38: Air supply fan drive circuit

39: exhaust fan drive circuit 40: damper drive circuit

The present invention relates to an air conditioner, and more particularly, to a method for controlling the air volume of a ventilation system in which the air volume of a fan can be adjusted in response to a relative measured value of VOC (volatile organic compound) concentration and a sudden change in VOC concentration during air cleaning. will be.

In the following description, the air conditioner includes an air conditioner and a ventilation system.

In general, an air conditioner is composed of a mechanical device that cools and heats a room by using a heat exchange process between a heat exchange medium and an ambient atmosphere that undergoes a phase change process while circulating a closed circuit, so as to cool the hot air in a room during summer. It refers to the air conditioner that is used for cooling and the air conditioner that is used as a heating fan to heat indoor cold air in winter.

An air conditioner having such a function is generally used in conjunction with a ventilation system inserted into a ceiling through a hole formed in a ceiling of a building, and the ventilation system introduces indoor air and exhausts it to the outside. It is composed of a process of supplying air and supplying air into the room.

In recent years, such a ventilation system has been increasing in use with an air conditioner due to the advantage of not taking up space in the room.

Hereinafter, an air conditioner according to the related art will be described with reference to the accompanying drawings.

FIG. 1 is an overall configuration diagram of a general air conditioner composed of an air conditioner and a ventilation system, and FIG. 2 is a block diagram of the air conditioner shown centering on the ventilation system.

In general, when the air conditioner is configured indoors and outdoors as shown in FIG. 1 and is cooled by the air conditioner 10, the ventilation system drives an air supply fan to convert outdoor air into and out of the heat exchanger. After cooling to a temperature similar to the room temperature through the (20), to be introduced into the room through the air supply unit 22.

In the case where the heating operation is performed through the air conditioner 10, the indoor air is passed through the circulation circuit opposite to the circulation direction during the cooling operation and passed through the exhaust unit 24 and the heat exchanger 20. To be exhausted.

Referring to the configuration of the ventilation system for performing the air cleaning in the configuration of such an air conditioner as follows.

As shown in FIG. 2, the ventilation system controls the overall system, detects the VOC concentration, and controls the air supply fan drive and the intake fan drive based on the control unit 31 to purify the air in the room, and a damper for adjusting the air volume. A damper position detection sensor 36 for detecting the position of the gas, a VOC sensor 37 for detecting the VOC (volatile organic compound) concentration of the indoor air, and an exhaust fan for driving the exhaust fan to suck the polluted air in the room An air supply filter (not shown) for removing contaminants of the sucked air, and an air supply for driving an air supply fan to supply clean air purified through the air purification filter to the room And a damper driving circuit 40 for driving the damper according to the detection result of the damper position detecting sensor 36 when the air volume is determined by the fan driving circuit 38 and the control of the control unit 31.

Here, reference numeral 34 is a remote controller for inputting a signal for controlling the operation of the ventilation system by the user's selection, and 35 is an indoor unit of the air conditioner.

Polluted or stagnant air in the room contains a large amount of VOCs (Volatile Organic Compounds), and the air in these enclosed spaces has very unpleasant and harmful effects on the human body such as respiratory diseases, allergic skin diseases and headaches.

Therefore, when several people stay in an enclosed space, such as an office or a vehicle, it is necessary to purify the polluted air in the room and supply fresh and fresh air.

In this case, the air cleaning function using the ventilation system as shown in FIGS. 1 and 2 is used.

When the user executes the air cleaning function, the exhaust fan is first driven under the control of the controller 31 to suck the polluted air in the room through the exhaust unit 24.

In addition, the air sucked through the exhaust part 24 passes through an air purification filter (not shown) in the total heat exchanger 20. At this time, dust or organic compounds contained in the air through the air purification filter. And other contaminants are removed.

Subsequently, the air supply fan is driven under the control of the control unit 31 to supply clean air passing through the air purification filter to the room through the air supply unit 22.

The air flow control method of the ventilation system having the air cleaning function as described above will be described with reference to FIG. 3.

When the user sets the air cleaning function of the ventilation system to automatic operation, first, the stabilization of the VOC sensor 37 is performed, and the stabilization time of the VOC sensor 37 has passed the set time (typically, 3 minutes). It is determined whether or not (S1).

As a result (S1), when the stabilization time of the VOC sensor 37 elapses, the VOC value detected by the current VOC sensor 37 is read (S2).

At this time, when the VOC sensor value is 3V or more, ① recognizes the high concentration and operates the strong air volume of the ventilation system to perform the air cleaning (S3, S4).

On the other hand, if the VOC sensor value is 2V or more and 3V or less, ② recognize the medium concentration to operate the air volume of the ventilation system to medium wind (S5, S6), and if the VOC sensor value is 2V or less, ③ recognize the low concentration, the air volume of the ventilation system To drive in a mild wind (S7).

Conventional ventilation system, as shown in Table 1 below, by supplying a comfortable clean air to the room by controlling the air volume of the fan according to the VOC concentration detected through the VOC sensor 37.

VOC concentration Air flow ① 3.0V or more gale ② 2.0V or more ~ 3.0V or less A stroke ③ 2.0V or less Breeze

However, the ventilation system according to the related art described above has the following problems.

The ventilation system of the prior art controls the air volume of the air supply and exhaust fan in three stages (strong wind, heavy wind, and weak wind) according to the absolute value of the VOC concentration. It could not cope efficiently with the relative measured value and the rapid change of VOC concentration.

In other words, if the amount of change in the VOC concentration suddenly increases due to indoor smoking or a sudden increase in the number of people, the air volume is controlled solely based on the absolute value of the VOC concentration, despite the rapid deterioration of indoor air. There was a difficult issue.

The present invention is to solve such a problem of the ventilation system of the prior art, by controlling the air volume of the fan in response to the relative measured value of the VOC (volatile organic compound) concentration and the sudden change of the VOC concentration during air cleaning, It is an object of the present invention to provide a method for controlling air volume of a ventilation system to improve efficiency.

Air flow control method of the ventilation system according to the present invention for achieving the above object comprises the steps of reading the initial VOC value (V _O ) and the current VOC concentration value (V _New ); Obtaining a relative VOC concentration value V _New -V _O and a VOC concentration change amount V _New -V _Old using the initial VOC value V _O and the current VOC concentration value V _New ; Determining a level of the VOC concentration by comparing a reference level preset in a plurality of steps with the relative VOC concentration value V _New -V _O ; Determining a level of the VOC concentration change amount by comparing the reference level preset in a plurality of steps with the VOC concentration change amount (V _New -V _Old ); And controlling the driving intensities of the air supply fan and the exhaust fan according to the determined level of the VOC concentration and the level of the VOC concentration change amount.

Other objects, features and advantages of the present invention will become apparent from the following detailed description of embodiments taken in conjunction with the accompanying drawings.

A preferred embodiment of the airflow control method of the ventilation system according to the present invention will be described with reference to the accompanying drawings.

4 and 5a to 5e is a flow chart illustrating a method for controlling air volume during air cleaning through the ventilation system of the present invention.

In the present invention, the VOC sensor 37 uses a sensor for measuring the relative value of the VOC concentration.

In addition, the present invention is a reference factor for controlling the air volume of the ventilation system when cleaning the air, VOC concentration relative value (V _New -V _O ) and VOC concentration change amount (dV) (V _New- ) measured through the VOC sensor 37 V _Old ) at the same time.

This is a function as shown in the table in Table 2, by using a function as shown in the table, actively correct the air volume for the concentration of VOC (volatile organic compounds) increased by various causes, such as a rapid increase in stagnant air and indoor personnel It is to.

That is, the fuzzy membership function of Table 2 shows the correlation between the relative VOC concentration value (V _New -V _O ), VOC concentration change (dV) (V _New -V _Old ) and the air volume.

In accordance with the purge rules of Table 2 to determine whether the indoor pollution and the rapid increase in pollution control the air volume of the ventilation system.

VOC concentration relative value (V _New -V _O ) -1.0 or less -1.0 to -0.5 -0.5 to 0 0 to +0.5 +0.5 or more VOC concentration Amount of change (dV) (V _New -V _Old ) +0.2 or more A stroke gale gale A special lecture A special lecture +0.1 to +0.2 A stroke A stroke gale gale A special lecture 0 to +0.1 Breeze A stroke A stroke gale gale -0.1 to 0 Breeze Breeze A stroke A stroke gale -0.2 to -0.1 A mild wind Breeze Breeze A stroke A stroke -0.2 or less A mild wind A mild wind Breeze Breeze A stroke

As such, the method of controlling the air volume of the ventilation system by using the fuzzy membership function that considers both the relative VOC concentration value (V _New -V _O ) and the VOC concentration change (dV) (V _New -V _Old ) currently detected indoors is As follows.

As shown in FIG. 4, when the user sets the automatic operation of the air cleaning function in the ventilation system, it is first determined whether the stabilization time (normally, 3 minutes) of the VOC sensor 37 has elapsed (S10). .

As a result of the determination (S10), when the stabilization time of the VOC sensor 37 elapses, the initial value _VO of the VOC sensor 37 is simultaneously read (S11).

When a predetermined time elapses, the current indoor VOC concentration V _New is read (S12, S13), and the VOC concentration is obtained by using the initial value V _O and the current VOC concentration V _{New of} the read VOC concentration. The relative value (V _New -V _O ) and the VOC concentration change amount (dV) (V _New -V _Old ) are obtained (S14).

As described above, when the relative values of VOC concentration V _New -V _O and VOC concentration change amount dV (V _New -V _Old ) are obtained, a step for controlling the air volume of the ventilation system for performing air cleaning is performed.

In the present invention, the reference level for comparing with the relative VOC concentration value (V _New -V _O ) is divided into (A)>(B)>(C)> (D), and the VOC concentration change amount (dV) ( V _New -V _Old ) is divided into (a)>(b)>(c)>(d)> (e).

For example, the reference level (V) for the relative VOC concentration value (V _New -V _O ) is divided into +0.5, 0, -0.5, -1.0, and the VOC concentration change (dV) (V _New -V _The reference level (V) for _Old ) is divided into +0.2, +0.1, 0, -0.1, and -0.2. It is natural that the air volume can be controlled to further refine the size division of each reference level so that accurate and rapid ventilation is achieved.

First, the current VOC concentration relative value (V _New -V _O ) obtained in the step (S14) is compared with the reference level + 0.5V, 0V, -0.5V, -1.0V.

As a result of the comparison, when the current VOC concentration relative value (V _New -V _O ) is greater than or equal to the reference level + 0.5V (S15), the VOC concentration change amount (dV) (V _New -V _Old ) is referred to as the reference level + 0.2V, + Compare the air flow of the ventilation system with 0.1V, 0V, -0.1V and -0.2V.

When the current VOC concentration relative value (V _New -V _O ) is more than the reference level + 0.5V, as shown in Figure 5a, if the VOC concentration change amount (V _New -V _Old ) is more than the reference level + 0.2V And the exhaust fan is driven in a 'special wind' (S20, S21).

On the other hand, when the VOC concentration change amount (V _New -V _Old ) is more than the reference level + 0.1V and less than + 0.2V, the air supply fan and the exhaust fan are driven with 'special wind' (S22, S23).

On the other hand, when the VOC concentration change amount (V _New -V _Old ) is greater than or equal to the reference level 0V and less than + 0.1V, the air supply fan and the exhaust fan are driven in 'strong wind' (S24, S25).

On the other hand, when the VOC concentration change amount (V _New -V _Old ) is more than the reference level -0.1V and less than 0V, the air supply fan and the exhaust fan are driven in 'strong wind' (S26, S27).

On the other hand, if the VOC concentration change amount (V _New -V _Old ) is greater than or equal to the reference level -0.2V and less than -0.1V, the air supply fan and the exhaust fan are driven in a 'mid wind' (S28, S29).

On the other hand, if the VOC concentration change amount (V _New -V _Old ) is less than the reference level -0.2V, the air supply fan and the exhaust fan is driven in a 'mid wind' (S30).

When the comparison result shows that the current VOC concentration relative value (V _New -V _O ) is greater than or equal to the reference level 0V and less than or equal to + 0.5V (S31), the VOC concentration change amount dV (V _New -V _Old ) is referred to as the reference level. Compare the air volume of the ventilation system with + 0.2V, + 0.1V, 0V, -0.1V, and -0.2V.

When the current VOC concentration relative value (V _New -V _O ) is greater than or equal to the reference level 0V and less than + 0.5V, as shown in FIG. 5B, the VOC concentration change amount (V _New -V _Old ) is greater than or equal to the reference level + 0.2V. In the rear, the air supply fan and the exhaust fan are driven with 'special wind' (S40, S41).

On the other hand, when the VOC concentration change amount (V _New -V _Old ) is more than the reference level + 0.1V and less than + 0.2V, the air supply fan and the exhaust fan are driven in 'strong wind' (S42, S43).

On the other hand, when the VOC concentration change amount (V _New -V _Old ) is greater than or equal to the reference level 0V and less than + 0.1V, the air supply fan and the exhaust fan are driven in 'strong wind' (S44, S45).

On the other hand, if the VOC concentration change amount (V _New -V _Old ) is greater than or equal to the reference level -0.1V and less than 0V, the air supply fan and the exhaust fan are driven in a 'mid wind' (S46, S47).

On the other hand, if the VOC concentration change amount (V _New -V _Old ) is greater than or equal to the reference level -0.2V and less than -0.1V, the air supply fan and the exhaust fan are driven in a 'mid wind' (S48, S49).

On the other hand, when the VOC concentration change amount (V _New -V _Old ) is less than the reference level -0.2V, the air supply fan and the exhaust fan are driven in 'weak air' (S50).

When the comparison result shows that the current VOC concentration relative value (V _New -V _O ) is greater than or equal to the reference level -0.5V and less than or equal to 0V (S51), the VOC concentration change amount dV (V _New -V _Old ) is referred to as a reference level. Compare the air volume of the ventilation system with + 0.2V, + 0.1V, 0V, -0.1V, and -0.2V.

When the current VOC concentration relative value (V _New -V _O ) is greater than or equal to the reference level -0.5V and less than or equal to 0V, as shown in FIG. 5C, the VOC concentration variation amount (V _New -V _Old ) is greater than or equal to the reference level + 0.2V. In the rear, the air supply fan and the exhaust fan are driven in 'strong wind' (S60, S61).

On the other hand, when the VOC concentration change amount (V _New -V _Old ) is more than the reference level + 0.1V and less than + 0.2V, the air supply fan and the exhaust fan are driven in 'strong wind' (S62, S63).

On the other hand, when the VOC concentration change amount (V _New -V _Old ) is greater than or equal to the reference level 0V and less than + 0.1V, the air supply fan and the exhaust fan are driven in 'mid wind' (S64, S65).

On the other hand, when the VOC concentration change amount (V _New -V _Old ) is greater than or equal to the reference level -0.1V and less than 0V, the air supply fan and the exhaust fan are driven in 'mid wind' (S66 and S67).

On the other hand, when the VOC concentration change amount (V _New -V _Old ) is greater than or equal to the reference level -0.2V and less than -0.1V, the air supply fan and the exhaust fan are driven in 'weak air' (S68, S69).

On the other hand, when the VOC concentration change amount (V _New -V _Old ) is less than the reference level -0.2V, the air supply fan and the exhaust fan is driven in 'weak air' (S70).

When the comparison result shows that the current VOC concentration relative value (V _New -V _O ) is greater than or equal to the reference level -1.0V and less than or equal to -0.5V (S71), the VOC concentration change amount dV (V _New -V _Old ) is determined. The airflow of the ventilation system is controlled after comparison with the reference levels + 0.2V, + 0.1V, 0V, -0.1V and -0.2V.

When the current VOC concentration relative value (V _New -V _O ) is greater than or equal to the reference level -1.0V and less than or equal to -0.5V, as shown in FIG. 5D, the VOC concentration change amount (V _New -V _Old ) is greater than or equal to the reference level +0.2. If V or more, the air supply fan and the exhaust fan are driven in 'strong wind' (S80 and S81).

On the other hand, if the VOC concentration change amount (V _New -V _Old ) is more than the reference level + 0.1V and less than + 0.2V, the air supply fan and the exhaust fan are driven in 'mid-wind' (S82, S83).

On the other hand, when the VOC concentration change amount (V _New -V _Old ) is greater than or equal to the reference level 0V and less than + 0.1V, the air supply fan and the exhaust fan are driven in 'mid wind' (S84 and S85).

On the other hand, when the VOC concentration change amount (V _New -V _Old ) is greater than or equal to the reference level -0.1V and less than 0V, the air supply fan and the exhaust fan are driven in 'weak air' (S86, S87).

On the other hand, if the VOC concentration change amount (V _New -V _Old ) is the reference level -0.2V or more and -0.1V or less, the air supply fan and the exhaust fan are driven in 'weak air' (S88, S89).

On the other hand, if the VOC concentration change amount (V _New -V _Old ) is less than the reference level -0.2V, the air supply fan and the exhaust fan is driven in 'ultra wind' (S90).

When the comparison result shows that the current VOC concentration relative value V _New -V _O is less than or equal to the reference level -1.0 V (S71), the VOC concentration change amount dV (V _New -V _Old ) is referred to as the reference level + 0.2V. Control the airflow of the ventilation system after comparing with + 0.1V, 0V, -0.1V and -0.2V.

When the current VOC concentration relative value (V _New -V _O ) is less than the reference level -1.0V, as shown in Figure 5e, if the VOC concentration change amount (V _New -V _Old ) is greater than or equal to the reference level + 0.2V And the exhaust fan is driven in a 'mid wind' (S91, S92).

On the other hand, when the VOC concentration change amount (V _New -V _Old ) is more than the reference level + 0.1V and less than + 0.2V, the air supply fan and the exhaust fan are driven in 'mid wind' (S93, S94).

On the other hand, if the VOC concentration change amount (V _New -V _Old ) is greater than or equal to the reference level 0V and less than + 0.1V, the air supply fan and the exhaust fan are driven in 'soft air' (S95, S96).

On the other hand, when the VOC concentration change amount (V _New -V _Old ) is greater than or equal to the reference level -0.1V and less than 0V, the air supply fan and the exhaust fan are driven in 'weak air' (S97 and S98).

On the other hand, when the VOC concentration change amount (V _New -V _Old ) is greater than or equal to the reference level -0.2V and less than -0.1V, the air supply fan and the exhaust fan are driven in 'weak air' (S99, S100).

On the other hand, if the VOC concentration change amount (V _New -V _Old ) is less than the reference level -0.2V, the air supply fan and the exhaust fan is driven in 'ultra wind' (S101).

Therefore, the present invention uses the VOC concentration change amount (V _New -V _Old ) together with the relative value (V _New -V _O ) of the VOC concentration as the air volume control factor to efficiently cope with the case that the indoor pollution is sharply worsened. do.

That is, even if the VOC concentration change amount of the room suddenly increases, it is possible to efficiently maintain the cleanliness of the room.

The air volume control method of the ventilation system according to the present invention as described above has the following effects.

First, by using the VOC concentration change amount as the air volume control factor together with the relative value of the VOC concentration, it is possible to efficiently cope with the rapid indoor air pollution.

Second, to determine the pollution level of indoor air using various factors such as the relative value of VOC concentration and the variation of VOC concentration, and to control the air volume of the ventilation system according to the determined pollution level, the efficiency of air cleaning with the most suitable type of air volume Can be maximized.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the embodiments, but should be defined by the claims.

Claims (7)

Reading a VOC (volatile organic compound) initial value (V _O ) and a current VOC concentration value (V _New ); Obtaining a relative VOC concentration value V _New -V _O and a VOC concentration change amount V _New -V _Old using the initial VOC value V _O and the current VOC concentration value V _New ; Determining a level of the VOC concentration by comparing a reference level preset in a plurality of steps with the relative VOC concentration value V _New -V _O ; Determining a level of the VOC concentration change amount by comparing the reference level preset in a plurality of steps with the VOC concentration change amount (V _New -V _Old ); And, And controlling the driving intensity of the air supply fan and the exhaust fan according to the determined level of the VOC concentration and the level of the VOC concentration change amount. The method according to claim 1, wherein in the step of determining the levels of VOC concentration and VOC concentration variation in order to control the driving intensity of the air supply fan and the exhaust fan, Set the reference value for classifying the relative VOC concentration size as (A)> (B)> (C)> (D) and set the reference value for classifying the VOC concentration change size (a)> (b)> (c) > (d)> (e) air flow control method characterized in that it is set. The method of claim 2, When the user executes the air cleaning function, the VOC concentration relative value (V _New -V _O ) is set to reference levels (A), (B), (C), and (D) to control the driving strength of the air supply fan and the exhaust fan. ), As a result, when the relative VOC concentration value (V _New -V _O ) is greater than the reference level (A), the VOC concentration change amount (V _New -V _Old ) is a reference level (a), (b), (c), ( d), comparing with (e), As a result of the comparison, when the VOC concentration change amount V _New -V _Old is greater than the reference level (a), driving the air supply fan and the exhaust fan to a 'special wind'; When the VOC concentration change amount (V _New -V _Old ) is less than the reference level (a) and greater than (b), driving the air supply fan and the exhaust fan to a 'special wind'; If the VOC concentration change amount (V _New -V _Old ) is less than the reference level (b) and greater than (c), driving the air supply fan and the exhaust fan to a 'strong wind'; If the VOC concentration change amount (V _New -V _Old ) is less than the reference level (c) and greater than (d), driving the air supply fan and the exhaust fan to 'strong wind'; If the VOC concentration change amount (V _New -V _Old ) is less than the reference level (d) and greater than (e), driving the air supply fan and the exhaust fan to 'mid wind'; And when the VOC concentration change amount (V _New -V _Old ) is smaller than the reference level (e), driving the air supply fan and the exhaust fan to 'middle wind'. The method of claim 3, wherein If the relative VOC concentration value (V _New -V _O ) is less than the reference level (A) and greater than (B), the VOC concentration change amount (V _New -V _Old ) is the reference level (a), (b), (c ), (d) and (e), As a result of the comparison, when the VOC concentration change amount V _New -V _Old is greater than the reference level (a), driving the air supply fan and the exhaust fan to a 'special wind'; When the VOC concentration change amount (V _New -V _Old ) is less than the reference level (a) and greater than (b), driving the air supply fan and the exhaust fan to a 'strong wind'; If the VOC concentration change amount (V _New -V _Old ) is less than the reference level (b) and greater than (c), driving the air supply fan and the exhaust fan to a 'strong wind'; If the VOC concentration change amount (V _New -V _Old ) is less than the reference level (c) and greater than (d), driving the air supply fan and the exhaust fan to 'mid wind'; If the VOC concentration change amount (V _New -V _Old ) is less than the reference level (d) and greater than (e), driving the air supply fan and the exhaust fan to 'mid wind'; And when the VOC concentration change amount (V _New -V _Old ) is smaller than the reference level (e), driving the air supply fan and the exhaust fan to 'weak'. The method of claim 3, wherein If the relative VOC concentration value (V _New -V _O ) is less than the reference level (B) and greater than (C), the VOC concentration change amount (V _New -V _Old ) is the reference level (a), (b), (c ), (d) and (e), As a result of the comparison, when the VOC concentration change amount (V _New -V _Old ) is greater than the reference level (a), driving the air supply fan and the exhaust fan to 'strong wind', When the VOC concentration change amount (V _New -V _Old ) is less than the reference level (a) and greater than (b), driving the air supply fan and the exhaust fan to a 'strong wind'; If the VOC concentration change amount (V _New -V _Old ) is less than the reference level (b) and greater than (c), driving the air supply fan and the exhaust fan to 'mid wind'; If the VOC concentration change amount (V _New -V _Old ) is less than the reference level (c) and greater than (d), driving the air supply fan and the exhaust fan to 'mid wind'; If the VOC concentration change amount (V _New -V _Old ) is less than the reference level (d) and greater than (e), driving the air supply fan and the exhaust fan to 'weak'; And when the VOC concentration change amount (V _New -V _Old ) is smaller than the reference level (e), driving the air supply fan and the exhaust fan to 'weak'. The method of claim 3, wherein When the relative VOC concentration (V _New -V _O ) is less than the reference level (C) and greater than (D), the VOC concentration change amount (V _New -V _Old ) is the reference level (a), (b), (c ), (d) and (e), As a result of the comparison, when the VOC concentration change amount (V _New -V _Old ) is greater than the reference level (a), driving the air supply fan and the exhaust fan to 'strong wind', If the VOC concentration change amount (V _New -V _Old ) is less than the reference level (a) and greater than (b), driving the air supply fan and the exhaust fan to 'mid wind'; If the VOC concentration change amount (V _New -V _Old ) is less than the reference level (b) and greater than (c), driving the air supply fan and the exhaust fan to 'mid wind'; If the VOC concentration change amount (V _New -V _Old ) is less than the reference level (c) and greater than (d), driving the air supply fan and the exhaust fan to 'weak'; If the VOC concentration change amount (V _New -V _Old ) is less than the reference level (d) and greater than (e), driving the air supply fan and the exhaust fan to 'weak'; If the VOC concentration change amount (V _New -V _Old ) is less than the reference level (e), the air flow rate control method characterized in that it comprises the step of driving the air supply fan and the exhaust fan in the 'ultra wind'. The method of claim 3, wherein If the relative VOC concentration value (V _New -V _O ) is less than the reference level (D), the VOC concentration change amount (V _New -V _Old ) is the reference level (a), (b), (c), (d ) and (e), As a result of the comparison, when the VOC concentration change amount V _New -V _Old is greater than the reference level (a), driving the air supply fan and the exhaust fan to 'mid wind'; If the VOC concentration change amount (V _New -V _Old ) is less than the reference level (a) and greater than (b), driving the air supply fan and the exhaust fan to 'mid wind'; If the VOC concentration change amount (V _New -V _Old ) is less than the reference level (b) and greater than (c), driving the air supply fan and the exhaust fan to 'weak'; If the VOC concentration change amount (V _New -V _Old ) is less than the reference level (c) and greater than (d), driving the air supply fan and the exhaust fan to 'weak'; If the VOC concentration change amount (V _New -V _Old ) is less than the reference level (d) and greater than (e), driving the air supply fan and the exhaust fan to 'weak air'; If the VOC concentration change amount (V _New -V _Old ) is less than the reference level (e), the air flow rate control method characterized in that it comprises the step of driving the air supply fan and the exhaust fan in the 'ultra wind'.

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