KR100789711B1 - Control method of air cleaner - Google Patents

Abstract

A method of controlling an air cleaner is provided to prevent sleeping disturbance by operating the air cleaner silently when operating the air cleaner in a sleeping operation mode. In a method of controlling an air cleaner comprising a cabinet, an ion generator, a blowing fan, and an input part, the method comprises the steps of: selecting a sleeping operation mode in which the blowing fan is operated silently and an automatic operation mode in which the blowing fan is variably operated according to set conditions, and the ion generator generates cations and anions; selecting an MPI(Micro Plasma Ion) mode when selecting the sleeping operation mode; selecting a cation/anion on mode in which the ion generator generates both anions and cations and a cation on reservation mode in which the ion generator generates anions only and generates cations after a predetermined time when selecting the MPI mode; and converting the cation on reservation mode into the cation/anion on mode with the passage of a predetermined time.

Description

Control method of air cleaner {CONTROL METHOD OF AIR CLEANER}

1 is a perspective view showing a schematic view of an air cleaner according to the present invention;

Figure 2 is a perspective view of the ion generator of the air purifier according to the present invention,

3 is a block diagram of an air cleaner according to the present invention;

4 is an operation state diagram showing the operation of the display unit according to the sleep mode operation mode selection of the air purifier according to the present invention,

5 and 6 is a control flow chart of the air purifier according to the present invention.

Explanation of symbols on the main parts of the drawings

1: air cleaner 10: cabinet

11 air inlet 13 air outlet

20 ion generator 25 cation generator

27: negative ion generating unit 30: blowing fan

40: input unit 50: pollution detection sensor

51 dust sensor 53 gas sensor

60 display unit 70 control unit

The present invention relates to a control method of an air cleaner, and more particularly, to a control method of an air cleaner capable of quiet operation when operating in the sleep mode.

In general, an air purifier is provided with a plurality of filters to purify the air and a blower fan for air circulation to purify the air containing the dust and gas through the filter by the operation of the blower fan for air circulation. It is a device to clean the surrounding air.

Recently, an air cleaner having a function of MPI (Micro Plasma Ion) mode has been developed. The air cleaner cleans indoor air and blows positive and negative ions generated from the ion generator to increase ion concentration in the air, thereby increasing user's health and comfort.

The air purifier selectively operates in an automatic operation mode in which the blower fan is shifted in speed and in a sleep mode in which the blower fan is operated at low speed in accordance with conditions such as pollution of external air or a user's setting. Here, the ion generator is controlled to always generate both positive and negative ions regardless of the automatic operation mode and the sleep operation mode. On the other hand, the ion generator adopted in the air conditioner generates noise because discharge noise is generated in the process of generating cations.

However, the discharge noise is canceled by the daily living noise during the day of operation in the automatic operation mode of the conventional air cleaner, but there is a problem that such a discharge noise may interfere with the user's sleep at night operating in the sleep operation mode. .

Accordingly, it is an object of the present invention to provide a control method of an air purifier that can prevent sleep disturbance by quiet operation when driving in the sleep mode.

According to the present invention, there is provided a cabinet, an ion generator accommodated in the cabinet and having a cation generator and an anion generator, a blower fan for discharging ions generated from the ion generator to the outside of the cabinet, and an operation mode. In the control method of the air purifier comprising an input unit for selecting, the sleep operation mode for constant speed operation of the blower fan, the automatic operation mode for generating a positive ion and negative ions in the ion generator while shifting the blower fan according to a set condition Selecting a; Selecting a MPI mode when the sleep mode is selected; Selecting a cation / anion-on mode for generating both anions and cations in the ion generator when the MPI mode is selected, and a cation-on reservation mode for generating only positive ions from the ion generator and generating cations after a predetermined time; Switching to the cation / anion on mode after the predetermined time has elapsed.

The predetermined time may be a reservation time input through the input unit when the cation on reservation mode is selected. Therefore, the user can stop the drive of the cation generating unit for a desired time to perform a quiet operation.

The method may further include switching to the automatic operation mode after the waiting time input when the sleeping operation mode is selected.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to FIGS. 1 to 4.

The air cleaner 1 according to the present invention includes a cabinet 10 forming an appearance, an ion generator 20 accommodated in the cabinet 10, a blowing fan 30, and an input unit 40 for selecting an operation mode. And a display unit 60 on which driving information is displayed, and a control unit 70.

The cabinet 10 forms the appearance of the air cleaner 1. The cabinet 10 has an air inlet 11 through which air is introduced and an air outlet 13 through which air is discharged. On the other hand, the cabinet 10 is detachably mounted to the filter unit 15 with a plurality of filters (not shown) for cleaning the air introduced through the air inlet (11). In addition, the ion generator 20 and the blowing fan 30 are accommodated in the cabinet 10.

The ion generator 20 is housed inside the cabinet 10 to generate anions and cations. As shown in FIG. 2, the ion generator 20 includes a casing 21, a power supply 23, and a cation generator 25 generating cations and ozone by a power source provided from the power supply 23. , An anion generating unit 27 for generating an anion by the power supplied from the power supply unit 23.

The cation generator 25 is made of a ceramic plate, and is inserted into one side of the upper surface of the casing 21. Then, the plate surface of the cation generating portion 25 is exposed to the outside of the casing 21. The cation generator 25 includes a discharge electrode (not shown) and an induction electrode (not shown). A high voltage of positive component is applied between the discharge electrode and the induction electrode. Here, when a high voltage of the positive component is applied between the discharge electrode and the induction electrode, moisture in the air is ionized by plasma discharge to generate cations and ozone (O ₃ ) of hydrogen ions (H ⁺ ). In the cation generator 25, discharge noise is generated in the course of performing the discharge process.

The anion generator 27 is formed of a needle electrode and protrudes from the upper surface of the casing 21 at a position spaced apart from the cation generator 25 by a predetermined distance. On the other hand, since the structure and operation of the ion generator 20 is already known matters, detailed description thereof will be omitted.

The blowing fan 30 is accommodated in the cabinet 10. The blowing fan 30 rotates to discharge external air through the air inlet 11 through the filter unit 15 to the air discharge port 13. Here, the ion generator 20 is preferably mounted on the flow path of the air flowing by the blowing fan (30). Thus, ions generated in the ion generator 20 can be discharged to the outside. The blowing fan 30 is provided so that the rotation speed is variable. The drive and the shift are controlled by the control unit of the blowing fan 30.

The input unit 40 is provided for the user to select and input the set mode. The input unit 40 is a pollution mode detected by a pollution detection sensor such as driving speed, dust, dust, odor, etc. of the operation mode such as automatic, yellow dust, bedtime, deodorization, turbo wind, strong wind, weak wind, and breeze. It is provided to select and input whether or not to select the MPI, and the reservation time and waiting time to be described later. In this embodiment, the input unit 40 is illustrated as being provided as a button on the front of the cabinet 10, but is not limited to this may be provided in various ways such as a touch screen. Here, the control unit 70 stores the control method of the blower fan 30 and the ion generator 20 according to each operation mode.

On the other hand, the air cleaner 1 according to the present invention may further include a pollution degree sensor 50 for detecting the pollution degree of the air flowing into the air inlet (11). Pollution degree detecting sensor 50 is a dust sensor 51 for detecting the dust contained in the air flowing into the air inlet 11, and a gas sensor for detecting the gas and odor contained in the air flowing into the air inlet 11 (53). The pollution degree detected by the pollution detection sensor 50 is used as a basis for controlling the blowing fan 30.

The display unit 60 displays operation information of the air cleaner 1. As shown in FIG. 4, the display unit 60 displays the operation mode A being operated such as 'auto', 'yellow sand', 'sleep', and 'deodorize'. In addition, the display unit 60 displays a driving speed B of the blowing fan 30 such as 'turbo wind', 'strong wind', 'wet wind', and 'breeze'. In addition, the display unit 60 has a pollution degree (C) detected by the pollution degree sensor 50, such as 'dust', 'dust', 'smell', the reservation time and waiting time (D) and MPI selection (to be described later) ( E) may be displayed.

The controller 70 controls the driving of the blower fan 30 and the ion generator 20 by a control method set according to an operation mode selected by the user. Here, the operation mode has various operation modes such as a sleep operation mode, an automatic operation mode, a yellow dust operation mode, a deodorization operation mode, and the present embodiment will be described with reference to the sleep operation mode and the automatic operation mode.

The automatic driving mode shifts and drives the blower fan 30 according to the pollution degree detected by the pollution degree sensor 50, and both the cation generator 25 and the negative ion generator 27 to generate positive and negative ions. It is a driving mode.

The sleep mode is a mode in which the blower fan 30 operates at a constant speed at the lowest driving speed at which the noise is generated at the lowest speed, 'the breeze', and selectively drives the ion generator 20 depending on whether the user selects the MPI mode. When the waiting time input by the user during the operation in the sleep mode is elapsed, the controller switches to the automatic operation mode and operates.

On the other hand, if the MPI mode is not selected when the sleeping operation mode is selected, the driving of the ion generator 20 is stopped and the blower fan 30 is driven at a constant speed in a 'breeze'. Here, when the MPI mode is selected, the control unit 70 selects the cation on reservation mode and the cation / anion on mode again.

The cation / anion ON mode is an operation mode for driving both the cation generator 25 and the anion generator 27 to generate positive and negative ions.

The cation on reservation mode is an operation mode in which only the anion generator 27 is driven to generate only anion, and when a predetermined time elapses, the cation generator 25 is driven to switch to a cation / anion on mode. Here, the predetermined time is a reservation time input by the user in the input unit 40 after entering the cation on reservation mode.

On the other hand, the control unit 70 displays only the minimum information of the information displayed on the display unit 60 when driving in the sleep mode. For example, as shown in Figure 4, after selecting the sleep operation mode, 'sleep' is displayed (I). When the MPI mode is selected, 'sleep' and 'ON' of the MPI mode are displayed (II). When the cation on reservation mode is selected, 'sleep', 'ON', 'reservation time' and 'OFF reservation' of the MPI mode are displayed (III). When the input reservation time is reached, the display switches to the positive / negative on mode and displays 'sleep', 'ON' and 'reserved time' in the MPI mode (IV). Accordingly, power consumption can be reduced, and the user can prevent glare at bedtime.

Looking at the operation of the air purifier according to the present invention including such a configuration with reference to Figures 3 and 5 as follows.

First, it is determined whether the user selects the sleep operation mode by the input unit 40 (S1). If it is determined that the sleep operation mode is not present, the operation is performed in the automatic operation mode (S9). In the present embodiment, the operation in the automatic operation mode is described in step S9, but it is preferable that the operation in the operation mode input from the input unit 40, such as yellow sand operation mode or deodorization operation mode.

On the other hand, if it is determined that the sleep mode is selected in step S1, the standby time is input (S3). Here, the user inputs the waiting time through the input unit 40. Then, the control unit 70 operates in the sleep mode (S5). The control method of the control unit 70 entering and going to sleep mode will be described later.

In operation S7, it is determined whether the elapsed time after entering the sleep operation mode reaches the waiting time input in step S3. Here, when it is determined that the elapsed time reaches the sleep time input in step S3 after entering the sleep mode, the process moves to step S9 to operate in the automatic driving mode.

Next, referring to FIG. 3 and FIG. 6, the control method of the blower fan 30 and the ion generator 20 when operating in the sleep mode in step S5 of FIG. 5 will be described.

First, in step S5 enters the sleep mode (S51). Then, it is determined whether to enter the MPI mode (S52). Here, if it is determined that the user enters the MPI mode by selecting the MPI mode in the input unit 40, it is determined whether to enter the cation on reservation mode (S53). On the other hand, if it is determined in step S52 that the user did not enter the MPI mode because the user did not select the MPI mode in the input unit 40, both the cation generating unit 25 and the negative ion generating unit 27 stops driving (S54).

Meanwhile, when it is determined in step S53 that the user selects the cation on reservation mode from the input unit 40 to enter the cation on reservation mode, the user inputs a reservation time (S55). If it is determined in step S53 that the user selects the cation / anion on mode in the input unit 40 and enters the cation / anion on mode, both the cation generator 25 and the anion generator 27 are driven (S58).

On the other hand, when the user inputs the reservation time in step S55, the control unit 70 stops the drive of the cation generator 25, the negative ion generator 27 is driven (S56).

The controller 70 determines whether the input reservation time has elapsed after driving the negative ion generator 27 in step S56 (S57). Here, if it is determined that the input reservation time has elapsed after driving the negative ion generating unit 27, the process moves to step S58 to drive both the cation generating unit 25 and the negative ion generating unit 27.

As described above, the step of selecting the MPI (Micro Plasma Ion) mode when selecting the sleep mode, and in the cation / anion ON mode and ion generator that generates both anions and cations in the ion generator 20 when the MPI mode is selected Selecting a cation on reservation mode that generates only negative ions and generates cations after a predetermined time; and switching to cation / anion on mode after a predetermined time elapses, according to a user's selection when operating in a sleep mode. Since the driving of the cation generating unit can be stopped, sleep disturbance can be prevented.

In addition, the predetermined time is a reservation time input through the input unit when the cation on the reservation mode is selected, so that the user can be quiet operation for a desired time to prevent water disturbance, cation / anion on mode after the reservation time elapsed This allows the cation to regenerate after the user sleeps, providing optimal sleeping conditions.

As described above, according to the present invention, it is possible to provide a control method of an air cleaner that can prevent sleep disturbance by quiet operation when driving in the sleep mode.

Claims (3)

An air purifier comprising a cabinet, an ion generator accommodated in the cabinet and having a cation generator and an anion generator, a blower fan for discharging ions generated from the ion generator to the outside of the cabinet, and an input unit for selecting an operation mode. In the control method, Selecting a sleep operation mode for constant speed operation of the blower fan and an automatic operation mode for shifting the blower fan according to a set condition and generating positive and negative ions in the ion generator; Selecting a MPI mode when the sleep mode is selected; Selecting a cation / anion-on mode for generating both anions and cations in the ion generator when the MPI mode is selected, and a cation-on reservation mode for generating only positive ions from the ion generator and generating cations after a predetermined time; And switching to the cation / anion-on mode when the predetermined time has elapsed. The method of claim 1, The predetermined time is a control method of the air cleaner, characterized in that the reservation time input through the input unit when the cation on the reservation mode selection. The method of claim 2, The control method of the air purifier, characterized in that further comprising the step of switching to the automatic operation mode after the waiting time input when the sleep operation mode selection.

Images