Value dV of	High	Highest	High flow	Medium
concentration	(higher than +0.1)	flow rate	rate	flow rate
change of VOC	Medium	Highest	Medium	Lowest
	(over −0.1	flow rate	flow rate	flow rate
	below +0.1)
	Low	High flow	Medium	Lowest
	(below −0.1)	rate	flow rate	flow rate

Referring to [Table 2], if the concentration value of the volatile organic compounds is high, and the value of the concentration change is high or medium, thecontrol part30 determines that room is, not also polluted much presently, but also rapidly being polluted presently. According to this, thecontrol part30 controls such that the flow rate for cleaning or ventilating the room is set to the highest flow rate.

If the concentration value of the volatile organic compounds is high, and the value of the concentration change is low, thecontrol part30 determines that room is not being rapidly polluted presently, even though polluted much presently. If the concentration value of the volatile organic compounds is medium, and the value of the concentration change is high, thecontrol part30 determines that room is being rapidly polluted presently, even though polluted not so much presently. Accordingly, in above two cases, thecontrol part30 controls such that the flow rate for cleaning or ventilating the room is set to a high flow rate.

If the concentration value of the volatile organic compounds is medium, and the value of the concentration change is medium or low, or the concentration value of the volatile organic compounds is low, and the value of the concentration change is high, thecontrol part30 determines that room is polluted slightly presently, and a pollution rate is increasing gradually presently. Accordingly, in those cases, thecontrol part30 controls such that the flow rate for cleaning or ventilating the room is set to a medium flow rate.

Lastly, if the concentration value of the volatile organic compounds is low, and the value of the concentration change is medium or low, thecontrol part30 determines that room is clean presently, and not rapidly being polluted presently. According to this, thecontrol part30 controls such that the flow rate for cleaning or ventilating the room is set to the lowest flow rate.

In the meantime, referring to [Table 2], for controlling the air flow rate according to the concentration value of the volatile organic compounds, and the value of the concentration change, thecontrol part30 determines a level of the concentration value of the volatile organic compounds measured at theVOC sensor15 and a level of the value of the concentration change calculated presently.

The level of the concentration value is determined by comparing the concentration value measured at theVOC sensor15 to various reference values set in advance. The value of the concentration change is also determined by comparing the value of concentration change calculated presently to various reference values set in advance.

Once the concentration value and the value of concentration change are determined by above method, thecontrol part30 controls at least one of rotation speed of the first fan for supplying air to the room and the second fan for discharging air from the room, to control the flow rate of the air for the cleaning or ventilating the room. In this instance, each of the first fan and the second fan is rotated in one of various speeds inclusive of the highest speed, high speed, medium speed, and lowest speed.

When the first or second fan is rotated at the highest speed, the flow rate for cleaning or ventilating the room becomes the highest flow rate, and when the first or second fan is rotated at the high speed, the flow rate for cleaning or ventilating the room becomes the high flow rate. When the first or second fan is rotated at the medium speed, the flow rate for cleaning or ventilating the room becomes the highest flow rate, and when the first or second fan is rotated at the lowest speed, the flow rate for cleaning or ventilating the room becomes the lowest flow rate.

The flow chart inFIG. 4 shows the steps of a process for determining levels of the concentration value and the value of concentration change of the volatile organic compounds, and determining an air flow rate according to a result of the level determination, well. The air flow rate process will be described in more detail with reference toFIG. 4.

At first, thecontrol part30 determines if the present concentration value is higher than a first reference value, for an example, 3V, for determining a level of the concentration value of the volatile organic compounds. (S30). As a result of this, if the present concentration value is higher than the first reference value, thecontrol part30 determines that the present concentration value is high.

Once the level of the present concentration value is determined to be high in the step S30, thecontrol part30 determines a level of a value of concentration change at the present time. For this, thecontrol part30 determines if the calculated present value dV of the concentration change is higher than a third reference value, for an example, +0.1. (S31) As a result, if the present value dV of the concentration change is higher than the third reference value, thecontrol part30 determines that the level of the present value of the concentration change is high.

However, as a result of determination in the step S31, if the present value dV of the concentration change is not higher than the third reference value, thecontrol part30 determines if the present value dV of the concentration change is higher than a fourth reference value, for an example, −0.1V. (S32) As a result, if the present value dV of the concentration change is higher than the fourth reference value, thecontrol part30 determines that the present value dV of the concentration change is medium.

In the meantime, referring to [Table 2], if the present concentration value is high, and the present value dV of concentration change is high or medium, thecontrol part30 determines the flow rate of the air for cleaning or ventilating the room to be the highest flow rate. In this case, thecontrol part30 rotates at least one of the first fan and the second fan at the highest speed. (S71)

If the present value dV of concentration change is determined to be lower than the fourth reference value in the step S32, thecontrol part30 determines the value of the concentration change is low even if the present concentration value is high. According to this, as shown inFIG. 4 and [Table 2], thecontrol part30 rotates at least one of the first fan and the second fan at a high speed for having the high flow rate.

If the present concentration value is lower than the first reference value in the step S30, thecontrol part30 determines if the present concentration value is higher than the second reference value for determining the level of the present concentration value. (S40) As a result of this, if the present concentration value is higher than the second reference value, thecontrol part30 determines the present concentration value of being medium.

Then, thecontrol part30 determines if the present value of concentration change is higher than the third reference value, i.e., +0.1, for determining a level of the present value of concentration change. (S50). As a result of this, if the present value of concentration change is higher than the third reference value, thecontrol part30 determines that the present value of the concentration change is high while the present concentration value is medium.

Accordingly, in this case, as shown inFIG. 4 and [Table 2], thecontrol part30 rotates at least one of the first fan and the second fan to have the high flow rate. (S72).

In the meantime, if it is determined that the present value of concentration change is lower than the third reference value in the step S50, thecontrol part30 determines if the present value of the concentration change is higher than the fourth reference value, i.e., −0.1 for determining a level of the present value of the concentration change. (S60)

As a result of this, if the present value of concentration change is higher than the fourth reference value, thecontrol part30 determines that the present concentration value is medium, and the present value of concentration change is medium. Opposite to this, as a result of the determination, if the present value of concentration change is lower than the fourth reference value, thecontrol part30 determines that the present concentration value is medium, and the present value of concentration change is low.

According to this, in this case, as shown in [Table 2] andFIG. 4, thecontrol part30 rotates at least one of the first fan and the second fan at a medium speed to output a medium flow rate. (S73)

In the meantime, if it is determined that the present concentration value is lower than the second reference value as a result of determination in the step S40, thecontrol part30 determines that the present concentration value is low. Then, for determining the level of the present value of concentration change, thecontrol part30 determines if the present value of concentration change is higher than the third reference value, i.e., +0.1. (S41)

As a result of this, if the present value of concentration change is higher than the third reference value, thecontrol part30 determines that the present value of concentration change is high while the present concentration value is low. According to this, as shown in [Table 2] andFIG. 4, thecontrol part30 rotates at least one of the first fan and the second fan at a medium speed to output a medium flow rate. (S73).

Opposite to this, if it is determined that the present value of concentration change is lower than the third reference value, for determining a level of the present value of the concentration change, thecontrol part30 determines if the present value of concentration change is higher than the fourth reference value, i.e., −0.1. (S42)

As a result of this, if the present value of concentration change is higher than the fourth reference value, thecontrol part30 determines that the present value of concentration change is medium while the present concentration value is low. Opposite to this, if the present value of concentration change is lower than the fourth reference value, thecontrol part30 determines that the present value of concentration change is low while the present concentration value is low.

Accordingly, in this case, as shown in [Table 2] andFIG. 4, thecontrol part30 rotates at least one of the first fan and the second fan at the lowest speed to output a lowest flow rate. (S74)

In the meantime, thecontrol part30 repeats a process of reading a measured value at theVOC sensor15, and controlling the flow rate for cleaning, or ventilating the room with reference to the measured value during the air conditioning system is operated automatically. For this, upon finishing above process, thecontrol part30 determines if the air conditioning system is operated in the automatic operation mode. (S80)

As a result of the determination, if the air conditioning system is not operated in the automatic operation mode, i.e., operated manually, or stationary, thecontrol part30 terminates the flow rate control required for cleaning, or ventilating the room.

Opposite to this, as a result of the determination, if the air conditioning system is operated in the automatic operation mode, thecontrol part30 determines if a preset time period is passed after reading the measured value at theVOC sensor15. (S90)

If the preset time period is passed, thecontrol part30 reads the measured value at theVOC sensor15 again, and performs above steps starting from the step S20. However, if the preset time period is not passed, thecontrol part30 repeats the step S80 and the step S90 until the present time period is passed.

As has been described, the method for controlling an air flow rate of an air conditioning system of the present invention has the following advantages.

Not only absolute concentration, but also a value of concentration change of volatile organic compounds are taken into account in controlling the flow rate to the air required for cleaning, or ventilating the room. Therefore, in cleaning, or ventilating room air, not only a level of pollution of room air, but also rapid room air pollution is made to deal with.

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 invention. Thus, it is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

Claims

1. A method for controlling an air flow rate of an air conditioning system, comprising the steps of:

(a) measuring a concentration of volatile organic compounds in air, periodically;

(b) calculating a value of concentration change from concentration values measured at the present time and in the past; and

(c) controlling the flow rate of air for cleaning or ventilating a room with reference to the present concentration and value of concentration change.

2. The method as claimed inclaim 1, wherein the value of concentration change in the step (b) is a difference of a concentration value measured at the present time and a concentration value measured right before.

3. The method as claimed inclaim 1, wherein the flow rate of the air for cleaning or ventilating a room includes a highest flow rate, a high flow rate, a medium flow rate, and a lowest flow rate.

4. The method as claimed inclaim 3, wherein the flow rate of the air for cleaning or ventilating a room is controlled to be the highest flow rate when the concentration value is high, and the value of concentration change is high or medium.

5. The method as claimed inclaim 3, wherein the flow rate of the air for cleaning or ventilating a room is controlled to be the high flow rate when the concentration value is high, and the value of concentration change is low, or the concentration value is medium, and the value of concentration change is high.

6. The method as claimed inclaim 3, wherein the flow rate of the air for cleaning or ventilating a room is controlled to be the medium flow rate when the concentration value is medium, and the value of concentration change is medium or low, or the concentration value is low, and the value of concentration change is high.

7. The method as claimed inclaim 3, wherein the flow rate of the air for cleaning or ventilating a room is controlled to be the lowest flow rate when the concentration value is low, and the value of concentration change is medium of low.

8. The method as claimed inclaim 1, wherein the flow rate of the air for cleaning the room is controlled by controlling a rotation speed of a fan which draws air from the room and discharges the air to the room, again.

9. The method as claimed inclaim 1, wherein the flow rate of the air for ventilating the room is controlled by controlling a rotation speed of a fan which draws outdoor air and discharges the outdoor air to the room.

10. The method as claimed inclaim 1, wherein the flow rate of the air for ventilating the room is controlled by controlling a rotation speed of a fan which draws room air and discharges the room air to an outside of the room.

11. The method as claimed inclaim 1, wherein the step (c) includes the steps of;

(c1) determining a level of the concentration value measured at the present time,

(c2) determining a level of the value of the concentration change calculated at the present time, and

(c3) controlling a rotation speed of at least one of a first fan for supplying air to the room and a second fan for discharging air from the room with reference to the levels of the concentration value and the value of the concentration change.

12. The method as claimed inclaim 11, wherein the step (c1) includes the step of comparing the measured concentration value to various reference values.

13. The method as claimed inclaim 11, wherein the step (c2) includes the step of comparing the calculated value of concentration change to various reference values.

14. The method as claimed inclaim 11, wherein the first fan and the second fan rotate at one of speeds inclusive of a highest speed, a high speed, a medium speed, and a lowest speed, respectively.

15. The method as claimed inclaim 14, wherein the (c3) step includes the step of rotating at least one of the first fan and the second fan at the highest speed when the concentration value is high, and the value of the concentration change is high or medium.

16. The method as claimed inclaim 14, wherein the (c3) step includes the step of rotating at least one of the first fan and the second fan at the high speed when the concentration value is high, and the value of the concentration change is low.

17. The method as claimed inclaim 14, wherein the (c3) step includes the step of rotating at least one of the first fan and the second fan at the high speed when the concentration value is medium, and the value of the concentration change is high.

18. The method as claimed inclaim 14, wherein the (c3) step includes the step of rotating at least one of the first fan and the second fan at the medium speed when the concentration value is medium, and the value of the concentration change is medium or low.

19. The method as claimed inclaim 14, wherein the (c3) step includes the step of rotating at least one of the first fan and the second fan at the medium speed when the concentration value is low, and the value of the concentration change is high.

20. The method as claimed inclaim 14, wherein the (c3) step includes the step of rotating at least one of the first fan and the second fan at the lowest speed when the concentration value is low, and the value of the concentration change is medium or low.