KR20080101306A - Circuit for controlling noise of air cleaner and methed thereof - Google Patents

Abstract

A circuit for controlling noises of an air cleaner and a method thereof are provided to improve stillness of an air cleaner without decreasing the air purification efficiency by generating driving sound much lower than surrounding noise based on sensing of the indoor noises. A controller(11) which consists of a microcomputer controls the operation of an air cleaner, and a signal input unit(13) inputs the operation information that a user selects to the controller. A power unit(15) supplies the power for driving the controller and the air cleaner by the control of the signal input unit, and a noise sensor(17) senses the noises around the air cleaner while operating the air cleaner. According to the sound level sensed by the noise sensor, a fan motor drives the driving sound lower than the sensed noise level.

Description

Circulation for controlling noise of air cleaner and methed

1 is a circuit diagram of a noise control circuit of an air purifier according to the present invention.

2 is an operation timing diagram of FIG. 1.

3 is a graph showing the relationship between the ambient noise measured using the noise sensor shown in FIG. 1 and the driving sound level of the fan motor during the automatic mode driving;

FIG. 4 is a graph illustrating a relationship between ambient noise and fan motor driving sound levels measured using the noise sensor and the dust sensor shown in FIG. 1 during manual mode driving; FIG.

FIG. 5 is a graph illustrating a relationship between ambient noise measured using the noise sensor shown in FIG. 1 and driving sound levels of a fan motor during manual mode driving.

6 is an operation flowchart of the noise control circuit of the air purifier according to the present invention.

Figure 7 is a sectional perspective view illustrating an installation example of the noise sensor according to the present invention.

Explanation of symbols on the main parts of the drawings

11 control unit 13 signal input unit

15: power supply unit 17: noise sensor

19: dust sensor 21: infrared sensor

23: fan motor

The present invention relates to a noise control circuit and a method of the air purifier, and more particularly, to a noise control circuit and an method of the air purifier that can improve the quietness so that the driving sound of the fan motor is lower than the ambient noise of the room. will be.

In general, the air cleaner is a device that cleans the air by removing dust, bacteria and odors in the indoor air, the dust and odor contained in the indoor air sucked in accordance with the operation of the air circulation blower fan. It is purified as it passes, and the purified air is discharged back into the room. These air cleaners are increasing in demand due to air pollution, especially early spring yellow dust.

The air cleaner measures the pollution level such as the ambient dust concentration in the room by sensors, and changes the rotational speed of the blower fan according to the pollution level to purify the air. That is, if the pollution level is low, the blowing fan is rotated at a slow speed, and if the pollution level is high, the air is rotated at a high speed to purify the air within a short time.

However, the air cleaner generates a driving sound of a fan motor that drives a blower fan during driving. The driving sound of the fan motor varies depending on revolutions per minute (RPM). That is, the driving sound of the fan motor is small when the RPM is small, but when the RPM is increased, this driving sound may also be recognized as a noise. Such noise may be uncomfortable for a sound-sensitive user. In particular, when the user sleeps, such noise may interfere with the sound sleep.

Therefore, the Korean Patent No. 10-0652801 discloses a technology that can reduce the noise caused by the change of the wind to the maximum by slowing the user so that the user does not feel the change in the air volume according to the pollution when the silent mode is selected during automatic operation.

The noise control method according to the prior art is to change the rotational speed of the blower fan to be slower than normal operation so that the user does not feel the noise caused by the air volume change when the silent mode is selected during the automatic operation of the air cleaner to maximize the noise due to the air volume change Suppress Also, even when the silent mode is not selected, if the infrared sensor detects a person's approach, the control unit changes the blowing fan to rotate slowly so that the user does not feel the air volume due to the change in pollution degree such as dust concentration. Minimize the noise caused by the air volume change.

Accordingly, a user who is sensitive to sound or near the air cleaner may reduce discomfort caused by driving noises of the blowing fan and the fan motor, and may also increase quietness at night or at bedtime.

However, the noise control method of the air purifier according to the prior art reduces the rotational speed of the blower fan regardless of the ambient noise level when the silent mode is selected during automatic operation or when there is a person within a certain distance from the air purifier. There was a problem.

Accordingly, an object of the present invention is to detect the noise level in the room to drive the fan motor so that the driving noise is generated less than the ambient noise noise control circuit of the air purifier that can improve the quietness without lowering the air purification efficiency And its method.

The noise control circuit of the air purifier according to the present invention for achieving the above object comprises a control unit for controlling the operation of the air cleaner comprises a microcomputer, a signal input unit for inputting the operation information and other operation signals selected by the user to the control unit; A power supply unit for supplying power for driving the air cleaner main body and the control unit by the control of the signal input unit, a noise sensor for detecting the ambient noise level in the room during the operation of the air cleaner, and the noise level detected by the noise sensor And a fan motor which drives the level of the driving sound to be lower than the sensed noise level by varying the RPM per minute under the control of the controller.

The noise sensor is composed of a microphone and measures the ambient noise in the room at a predetermined measurement interval Δt in a state where the fan motor is turned off.

Noise control method of the air purifier according to the present invention for achieving the above object is controlled by the control unit to drive the air purifier by the power of the power supply according to the operation of the signal input unit of the user to purify the indoor air by the fan motor A first step, a second step of the noise sensor measuring ambient noise in the room while the air cleaner is driven, a third step of storing and calculating the ambient noise detected by the noise sensor, and the measured ambient noise value The control unit controls the fan motor so that the sum of the dust concentration measurement value A measured by the dust sensor and the value B of the intensity mode adjusted by the signal input unit coincides with the level of the driving sound of the fan motor. The fourth step of adjusting the RPM (rpm) and the second step if it is determined that the predetermined measurement interval (Δt) has elapsed after adjusting the RPM of the fan motor (RPM). In the fifth step of back-up, after determining the predetermined measurement interval Δt after adjusting the RPM of the fan motor, if the elapsed time does not pass, the dust sensor controls the indoor air. And a sixth step of measuring the dust concentration and feeding back to step 3.

In the noise sensor, the ambient noise of the room is measured while the fan motor is turned off or the RPM is low, or without the fan motor being turned off.

The calculated ambient noise in the third step is obtained by averaging or integrating a value of a predetermined number of times of measurement.

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

1 is a circuit diagram of a noise control circuit of an air purifier according to the present invention.

The noise control circuit of the air purifier according to the present invention includes a control unit 11, a signal input unit 13, a power supply unit 15, a noise sensor 17, a dust sensor 19, an infrared sensor 21, and a fan motor 23. It includes.

The control unit 11 is composed of a microcomputer to control the operation of the air cleaner.

The signal input unit 13 includes a remote control receiver or an operation switch to turn on / off the power of the air cleaner main body, and input operation information and other operation signals selected by the user to the control unit 11.

The power supply unit 15 supplies power for driving the air cleaner main body and the control unit 11 under the control of the signal input unit 13.

Noise sensor 17 is composed of a microphone and detects the ambient noise level during operation of the air cleaner to transmit to the control unit (11). In the above, the noise sensor 17 recognizes that there is a high level of dust in the room if a person has a large detected noise level.

The dust sensor 19 detects a pollution degree of dust in the room by measuring the dust concentration of the unpurified air sucked through the air inlet (not shown) of the main body, and the infrared sensor 21 is installed on the air cleaner main body. When the approach of the person is detected by detecting whether the approach of the noise sensor (17) is recognized that the concentration of dust in the room is high.

The fan motor 23 is composed of a breathless motor, an inverter motor, a DC motor, or the like, and drives a blowing fan (not shown) that sucks air into the main body. In the above, the fan motor 23 controls the revolution per minute (RPM) of the blowing fan under the control of the control unit 11 according to the noise level detected by the noise sensor 17 when the air cleaner is in the automatic mode. As the detected noise level goes from high to low, the dust concentration in the room is higher, so the fan speed is increased in order to purify the indoor air quickly.

The noise sensor 17 measures ambient noise of the room at a predetermined measurement interval Δt in a state in which the fan motor 23 is turned off, and transmits the noise to the control unit 11 as shown in FIG. 2.

In addition, the noise sensor 17 measures ambient noise in the room at a predetermined measurement interval Δt in a state in which the fan motor 23 has a low RPM and a low noise level, or measures the fan motor 23 by using the fan motor 23. It is also possible to measure continuously without turning off.

3 is a graph showing the relationship between the ambient noise measured using the noise sensor () shown in FIG. 1 and the driving sound level of the fan motor 23 during the automatic mode driving.

In the case where the air cleaner is driven in the automatic mode, the fan motor 23 has a level of driving noise lower than the measured value of the ambient noise measured by the noise sensor 17 at the time of sleep or activity by the user, as shown in FIG. 3. It is driven while maintaining. Therefore, the driving sound of the fan motor 23 is lower than the ambient noise so that the user does not feel uncomfortable due to the driving sound of the fan motor 23.

FIG. 4 is a graph showing the relationship between the ambient noise measured using the noise sensor 17 and the dust sensor 19 shown in FIG. 1 and the driving sound level of the fan motor 23 during manual mode driving.

When the air cleaner is driven in the manual mode and the noise sensor 17 and the dust sensor 19 are detected, the driving sound of the fan motor 23 is changed according to the level of dust concentration detected by the dust sensor 19. . That is, when the level of the dust concentration detected by the dust sensor 19 becomes higher based on the ambient noise detected by the noise sensor 17, the driving sound of the fan motor 23 is also changed.

Thus, when the dust concentration detected by the dust sensor 19 is a low level as shown in (a) or a medium level as shown in (b), the driving sound of the fan motor 23 is the noise level detected by the noise sensor 17. Occurs lower.

However, if the dust concentration detected by the dust sensor 19 is at a high level such as (c), the rotation speed of the fan motor 23 should be increased to increase the amount of intake of air into the main body to purify the air quickly. The sound is generated higher than the noise level detected by the noise sensor 17.

5 is a graph showing the relationship between the ambient noise measured using the noise sensor () shown in FIG. 1 and the driving sound level of the fan motor 23 during manual mode driving.

According to the state of the operation switch of the signal input unit 13 when the air cleaner is driven in the manual mode and the dust sensor 19 is 'off' so that only the noise sensor 17 detects the ambient noise in the 'on' state. The drive sound of the motor 23 is changed. That is, the driving sound of the fan motor 23 is also changed as the operation switch of the signal input unit 13 is adjusted to a weak mode, a medium mode, or a strong mode based on the ambient noise detected by the noise sensor 17.

Accordingly, when the operation switch of the signal input unit 13 is adjusted to a weak mode as shown in (a) or to an intermediate mode as shown in (b), the driving sound of the fan motor 23 is higher than the noise level detected by the noise sensor 17. Occurs low.

However, since the rotation speed of the fan motor 23 is increased when the operation switch of the signal input unit 13 is adjusted to a high mode as shown in (c), the driving sound is generated higher than the noise level detected by the noise sensor 17.

6 is an operation flowchart of the noise control circuit of the air purifier according to the present invention.

Referring to Figure 6 describes the operation of the noise control method of the air cleaner of the above-described configuration.

First, referring to step 1 (S1), when a user applies a driving signal by operating the signal input unit 13, the controller 11 causes the air cleaner to be 'on' by the power of the power source unit 15. To control. Accordingly, the fan motor 23 is driven to purify the indoor air.

Referring to step 2 (S2), the noise sensor 17 detects ambient noise in the room. At this time, the noise sensor 17 measures the ambient noise of the room in the state in which the fan motor 23 is off, as shown in FIG.

In addition, the noise sensor 17 measures ambient noise in the room at a predetermined measurement interval Δt in a state in which the fan motor 23 has a low RPM and a low noise level, or measures the fan motor 23 by using the fan motor 23. It is also possible to measure continuously without turning off.

Referring to step 3 (S3), the ambient noise detected by the noise sensor 17 is stored and calculated. In this case, the calculated ambient noise may be obtained by averaging or integrating a value of a predetermined number of measurements.

And referring to step 4 (S4), the control unit 11 is adjusted to the measured ambient noise value by the dust concentration measurement value (A) measured by the dust sensor 19 and the operation switch of the signal input unit 13 The RPM of the fan motor 23 is adjusted so that the sum of the values B of the intensity modes matches the driving sound of the fan motor 23. The dust concentration measurement value (A) above measures the dust concentration of the unpurified air sucked through the air intake port (not shown) of the main body. In addition, the driving sound of the fan motor 23 measures and stores the volume generated for each RPM and converts the data into table values.

Referring to step 5 (S5), in step 4 (S4), the sum of the ambient noise value plus the dust concentration measurement value (A) and the adjusted intensity mode value (B) coincides with the driving sound of the fan motor 23. After controlling the RPM of the fan motor 23 so that the control unit 11 determines whether a predetermined measurement interval Δt has elapsed.

At this time, if the predetermined measurement interval Δt has not elapsed, the control unit 11 controls the dust sensor 19 to measure the dust concentration of the indoor air as in step 6 (S6), and then proceeds to step 3 (S3). Feedback.

However, if a predetermined measurement interval Δt has passed, the control unit 11 controls to feed back to step 2 (S2) so that the noise sensor 17 measures the ambient noise.

Therefore, the present invention has the advantage of improving the quietness without deteriorating the air purification efficiency by driving the fan motor to generate a driving sound smaller than the ambient noise by sensing the ambient noise level in the room.

As described above, the present invention is only one embodiment, and the present invention is not limited to the above-described embodiments, and various modifications may be made by those skilled in the art within the technical spirit of the present invention. It is possible.

Claims (7)

A control unit for controlling the operation of the air cleaner composed of a microcomputer, A signal input unit for inputting driving information and other operation signals selected by the user to the controller; A power supply unit supplying power for driving the air cleaner main body and the control unit by the control of the signal input unit; A noise sensor for detecting an ambient noise level in the room during the operation of the air cleaner; An air purifier having a fan motor driven by comparing the level of driving sound with the detected noise level by varying the number of revolutions per minute (RPM) by the control of the controller according to the noise level detected by the noise sensor. Noise control circuit. The noise control circuit of claim 1, wherein the noise sensor comprises a microphone. The noise control circuit of claim 1, wherein the noise sensor measures ambient noise of a room at a predetermined measurement interval Δt in a state where the fan motor is turned off. A first step of controlling the controller to drive the air cleaner by the power of the power supply unit according to an operation of the signal input unit of the user to purify the indoor air by the fan motor; A second step of measuring an ambient noise of a room by a noise sensor while driving the air cleaner; A third step of storing and calculating the ambient noise detected by the noise sensor; The sum of the measured ambient noise value and the dust concentration measurement value (A) measured by the dust sensor and the value (B) of the intensity mode adjusted by the signal input unit is equal to the level of the driving sound of the fan motor. A fourth step of controlling, by the controller, the RPM of the fan motor; A fifth step of feeding back to the second step after determining whether a predetermined measurement interval Δt has elapsed after adjusting the RPM of the fan motor; After adjusting the RPM of the fan motor by determining whether a predetermined measurement interval Δt has elapsed, and if it has not elapsed, the dust sensor measures the dust concentration of the indoor air under the control of the controller. Noise control method of the air cleaner comprising a sixth step of feeding back to 3. The method of claim 4, wherein the noise sensor measures ambient noise in the room while the fan motor is turned off or RPM is low. The noise control method according to claim 4, wherein the noise sensor continuously measures the ambient noise of the room without turning off the fan motor. The noise control method of claim 4, wherein the calculated ambient noise is obtained by averaging or integrating a value of a predetermined number of times of measurement.

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