KR102085135B1 - Method for Indicating Fine Dust Information Released from Air Outlet of Vaccum Cleaner and Vaccum Cleaner Using Same - Google Patents

Abstract

The embodiment relates to a vacuum cleaner for discharging intake air after purifying the intake air using an exhaust filter, including: an exhaust pollution level detection unit for detecting the pollution level of exhaust air discharged through the exhaust filter; a control unit for generating a control signal for outputting pollution level-related information of the exhaust air; and a pollution information output unit for outputting the pollution level-related information according to the control signal.

Description

Method for Indicating Fine Dust Information Released from Air Outlet of Vaccum Cleaner and Vaccum Cleaner Using Same}

The present embodiment relates to a method of displaying information on fine dust discharged from a vacuum cleaner air outlet and a vacuum cleaner using the same.

The contents described below merely provide background information related to this embodiment and do not constitute a prior art.

The vacuum cleaner sucks the outside air by the suction force by the rotational force of the motor, passes through the exhaust filter provided therein, and exhausts the exhaust air outside.

In general, various dusts or foreign substances in the place cleaned by the vacuum cleaner are included in the air sucked by the vacuum cleaner, and after the suction of the vacuum cleaner, the dust or foreign matter is collected in the dust container inside the vacuum cleaner dust collecting chamber and passes through the dust bucket. One air passes through the dust collecting filter and the exhaust filter in sequence and then is discharged to the outside.

Even through the exhaust filter, there is a possibility that the air discharged out of the vacuum cleaner contains fine dust having high pollution. Thus, in order to prevent a problem that a large amount of fine dust is contained in the exhaust air of the vacuum cleaner, a method of configuring the exhaust filter to have a fine dust removal function can be considered.

Conventional corded or cordless cleaners only emphasize the number of filters, types of filters (EPA, HEPA, etc.) and grades of filters used (E12, E13, E14, etc.) but do not provide any information on the quality of the exhaust air. to be.

Even when a vacuum cleaner is constructed such that the exhaust filter has a fine dust removal function, the vacuum cleaner user may not know how much fine dust is contained in the air discharged out of the vacuum cleaner unless there is a separate means. Therefore, the user of the vacuum cleaner can not only believe the filter grade of the vacuum cleaner exhaust filter notified by the vacuum cleaner manufacturer or the seller, and the vacuum cleaner user can feel anxiety about the possibility that a large amount of fine dust is discharged to the air outlet of the vacuum cleaner. There is a problem that you can only use a vacuum cleaner inside.

This embodiment aims to display information on the fine dust discharged from the air outlet in the vacuum cleaner.

According to an embodiment of the present invention, a vacuum cleaner for purifying and exhausting the suction air by using the exhaust filter, the exhaust pollution degree detection unit for detecting the pollution degree of the exhaust air discharged through the exhaust filter; A controller configured to generate a control signal for outputting pollution degree related information of the exhaust air; And a pollution information output unit configured to output the pollution degree related information according to the control signal.

According to another embodiment of the present invention, a vacuum cleaner for purifying and discharging the suction air by using the exhaust filter, the pollution degree of the exhaust air for detecting the pollution degree of the exhaust air discharged through the exhaust filter; A control process of generating a control signal for outputting pollution degree related information of the exhaust air; And a pollution information output process of outputting the pollution degree related information according to the control signal.

The present invention, the effect of resolving the anxiety of the user of the vacuum cleaner to the discharge of fine dust by implementing a vacuum cleaner to have a function to detect the degree of contamination of the fine dust of the air discharged through the exhaust filter of the vacuum cleaner to inform the information related to the pollution degree There is.

In addition, by detecting the fine dust pollution of the air sucked into the vacuum cleaner and compare it with the fine dust pollution of the exhaust air according to the comparison result there is an effect to increase the reliability of the product by informing the user of the pollution information of the exhaust air.

In addition, by informing the contamination information of the exhaust air of the vacuum cleaner has an effect of informing the replacement time of the filter.

In addition, there is an effect of providing the user's convenience by adding a diagnostic function that informs the strength of the suction force to lower the pollution of the exhaust air compared to the pollution of the suction air to inform the most efficient vacuum suction strength.

Figure 1a is a view showing the appearance of a stick type as a vacuum cleaner applicable as an embodiment of the present invention, Figure 1b is a view showing the appearance of a handy cleaner as a vacuum cleaner applicable as an embodiment of the present invention.
2 is a schematic cross-sectional view of the vacuum cleaner according to the present embodiment.
3 is a block diagram showing the inside of the drive control unit according to the present embodiment.
4 is a block diagram illustrating an air pollution information notification method according to the present embodiment.
5 is a block diagram illustrating an optimal suction force strength diagnostic method according to the present embodiment.

Hereinafter, some embodiments of the present invention will be described in detail through exemplary drawings. In adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used to refer to the same components as much as possible, even if displayed on different drawings. In addition, in describing the present invention, if it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

Figure 1a is a view showing the appearance of a stick type as a vacuum cleaner applicable as an embodiment of the present invention, Figure 1b is a view showing the appearance of a handy cleaner as a vacuum cleaner applicable as an embodiment of the present invention.

Vacuum cleaner according to the present embodiment, the canister (Canister) type of the method of cleaning by connecting the hose and the push rod to the main body with a wheel, the upright type consisting of the main body, the handle and the push rod, and the handle on the main body The suction port may be implemented in various forms such as a handy / stick type attached to the main body.

In addition, the vacuum cleaner according to the present embodiment may be implemented as a vacuum cleaner of various power supply methods such as wireless, wired, wired and wireless combined.

Hereinafter, the description of the vacuum cleaner according to the present embodiment will be described with reference to FIG. 1B which shows a handy cleaner that can easily visualize and explain the internal structure as an example. However, it will be apparent to those skilled in the art that the present embodiment is applicable to the stick type of FIG. 1A. .

In other words, in this embodiment, the order and function of the components passing through the components of the vacuum cleaner (for example, the intake port, the various sensors, the exhaust filter, and the exhaust port) in accordance with the flow of the suction air until the suction and discharge of the vacuum cleaner are meaningful. However, the present invention is not limited according to the positional relationship such as physical left and right, up and down or front and back between the components.

2 is a schematic cross-sectional view of the vacuum cleaner according to the present embodiment. As described above, FIG. 2 schematically illustrates the internal structure of FIG. 1B.

1B and 2, the vacuum cleaner 1 according to the present embodiment includes a user driving button 10, a suction port 20, a suction pollution degree sensor 32, a discharge pollution degree sensor 34, Dust bin 40, first exhaust filter 52, second exhaust filter 54, third exhaust filter 56, fourth exhaust filter 58, motor 60, internal exhaust port 70, drive control The unit 80, the function control unit 82 and the external exhaust port 90.

In addition, since the electrical connection between the power supply and the components in FIG. 2 will be apparent to those skilled in the art, their illustration is omitted.

As shown in Figure 1b and 2, the front side of the vacuum cleaner (1) is formed with a suction port 20 for sucking the outside air containing dust or foreign matter therein, the suction port 20 in the rear A dust container 40 is formed to collect the dust sucked through the 20, and the rear surface of the dust container 40 is provided with a motor 60 for generating a suction force, that is, the rear surface of the motor 60, that is, In the rear of the vacuum cleaner 1, an internal exhaust port 70 and an external exhaust port 90 are formed as exhaust ports for discharging air passing through the motor 60 to the outside of the vacuum cleaner 1.

When the vacuum cleaner 1 senses that the user driving button 10 is pressed by the user, the vacuum cleaner 1 supplies power to the internal motor 60 to rotate the motor 60, and the suction force by the rotation of the motor 60 is applied to the outside. After the air is sucked into the vacuum cleaner 1 and passed through an exhaust filter provided therein, the exhaust air is discharged out of the vacuum cleaner 1.

When the motor 60 of the vacuum cleaner 1 is operated, air containing various dusts and foreign matters is sucked into the suction port 20 and flows into the dust container 40. The air entering the dust container 40 is filtered by the first exhaust filter 52 installed between the dust container 40 and the motor 60 so that large particles and foreign matter are filtered out, and the first exhaust filter 52 is not filtered. The air containing the small dust that has not entered is introduced into the second exhaust filter 54.

The air passing through the first exhaust filter 52 is formed by the second exhaust filter 54, the third exhaust filter 56, and the fourth exhaust filter 58 provided between the motor 60 and the internal exhaust port 70. The purified air sequentially and the purified air are discharged to the outside of the vacuum cleaner 1 through the internal exhaust port 70 and the external exhaust port 90. In addition, in FIG. 2, four exhaust filters are provided as the first to fourth exhaust filters 52, 54, 56, and 58, but according to the exemplary embodiment, various exhaust filters including three or five exhaust filters may be provided. It is possible.

Inhalation contamination detection sensor 32 is a sensor for measuring the pollution of the air sucked into the suction port 20, that is, the suction air pollution. The position of the suction contamination detection sensor 32 may be installed adjacent to the suction port 20 based on the flow of the suction air. Here, the suction contamination detection sensor 32 is not an essential component of the vacuum cleaner 1 and may be selectively employed in the vacuum cleaner 1 according to the embodiment.

Exhaust pollution detection sensor 34 is a sensor for measuring the pollution degree of the exhaust air discharged through the exhaust filter. Here, the position of the exhaust pollution detection sensor 34 may be located between the third exhaust filter 56 and the fourth exhaust filter 58 or between the fourth exhaust filter 58 and the internal exhaust port 70. However, according to the embodiment, the position of the discharge pollution detection sensor 34 can be variously selected.

For reference, the first exhaust filter 52, also called a pre-filter, is a filter that functions to filter out garbage, hair, animal hair, pollen, lint, etc., which are relatively large in intake air.

The second exhaust filter 54, also called a medium filter, is a filter having a function of removing smaller dust, yellow dust particles, house dust mites, and the like from the dust passing through the first exhaust filter 52.

The third exhaust filter 56 may be implemented as an ultra low dust filter (ULPA filter) that has a collection rate of 99.99% or more for particles of 0.1 μm or more in air.

The fourth exhaust filter 58 is a deodorizing filter, and removes a causative agent of sick house syndrome such as volatile organic compounds (VOC) such as formaldehyde and toluene, living odor, living gas, and pet odor. It is a filter having.

Here, the first to fourth exhaust filters 52, 54, 56, 58 are not limited to the types of filters as described above, respectively, and may be implemented as filters having various functions according to embodiments.

In this embodiment, the air pollution degree that can be measured by the intake contamination detection sensor 32 and the discharge pollution detection sensor 34 is the concentration of fine dust or ultra fine dust, or the concentration of VOC components and odors contained in the air. Can be. In addition, according to the embodiment, the intake contamination sensor 32 and the discharge pollution sensor 34 having a function of measuring the degree of contamination of various objects may be selected.

In the following description of the present embodiment, it is assumed that the object to be detected by the intake contamination detection sensor 32 and the discharge pollution detection sensor 34 is assumed to be ultra-fine dust.

The function operation unit 82 receives a user's function operation input, such as a diagnosis command input and an output selection of the user, and a detailed operation thereof will be described later.

The drive control unit 80 receives a user's operation input to the vacuum cleaner 1 from the user drive button 10 and the function operation unit 82 and controls the operation of the vacuum cleaner 1 according to the user's operation input. Device.

3 is a block diagram showing the inside of the drive control unit according to the present embodiment.

As shown in FIG. 3, the driving control unit 80 according to the present embodiment includes a suction force selecting unit 301, a suction pollution degree detecting unit 302, a discharge pollution degree detecting unit 303, a control unit 305, and an output unit. 306, a motor driver 307, an output selector 308, and a diagnostic command receiver 309.

Here, the suction force selection unit 301, the suction contamination detection unit 302, the output selection unit 308 and the diagnostic command receiving unit 309 is not an essential component of the drive control unit 80, these components as necessary It may be selectively employed and implemented in the drive control unit 80.

Hereinafter, the operation of the vacuum cleaner 1 according to the present embodiment will be described with reference to FIGS. 1B to 3.

The suction force selecting unit 301 receives a signal corresponding to the driving suction input selected by the user driving button 10 when selecting the strength of the driving suction input such as strong, medium, or weak using the user driving button 10.

The control unit 305 generates a suction force of the vacuum cleaner 1 by controlling the motor driving unit 307 to drive the motor 60 according to the signal received from the suction force selection unit 301.

The inhalation contamination detection unit 302 calculates the pollution degree of the intake air by using the detection signal received from the intake contamination detection sensor 32.

The exhaust pollution degree detecting unit 303 calculates the pollution degree of the exhaust air by using a detection signal generated from the exhaust pollution degree sensor 34.

The controller 305 controls the output of the output unit 306 by generating a control signal with reference to the pollution degree of the discharged air received from the emission pollution degree detecting unit 303 and the preset pollution standard. The control signal may be a pollution degree signal indicating a pollution degree of the exhaust air. In this case, the output unit 306 displays the pollution degree related information of the exhaust air according to the received pollution degree signal. Here, the pollution degree related information of the exhaust air may be a variety of information such as the ultra-fine dust concentration of the exhaust air, the ratio of the pollution degree of the exhaust air to the pollution degree of the intake air, the optimum suction power.

The output unit 306 displays the ultra fine dust concentration detected by the exhaust pollution detection sensor 34 when the object detected by the exhaust pollution detection sensor 34 is the ultra fine dust concentration. For example, the output unit 306 is "good" when the ultrafine dust (PM 2.5) concentration of the discharged air is 0 to 15 ㎍ / ㎥, "normal", 16 to 35 ㎍ / ㎥, 36 to 75 ㎍ In the case of / m 3, the message “bad” and in the case of 76 μg / m 3 or more, display the message “very bad”.

The vacuum cleaner 1 may further include an intake contamination detector 302 for detecting a pollution degree of the air sucked into the inlet 20.

The inhalation pollution degree detection unit 302 calculates the pollution degree of the intake air using the detection signal generated from the inhalation pollution degree detection sensor 32.

The control unit 305 may be implemented to generate a control signal using the detection signal received from the suction contamination detection unit 302. For example, the control unit 305 generates a control signal for controlling the output unit 306 to output the air purifying capacity of the vacuum cleaner 1 according to the ratio of the pollution degree of the exhaust air to the pollution degree of the inhaled air.

In this case, the controller 305 controls the pollution rate ratio of the discharged air to the output unit 306 as a number to be output to the output unit 306, thereby increasing the user's reliability of the vacuum cleaner 1. In addition, by informing the user of the pollution information of the exhaust air of the vacuum cleaner 1, there is an effect of indicating the replacement time of the pollution degree measurement filter, that is, the ultra-fine dust filter among the filters provided, thereby increasing the convenience of use.

In addition, the control unit 305 is a signal indicating the ratio of the pollution rate of the discharge air to the intake air pollution degree, and a signal indicating the result of comparing the pollution degree of the discharge air received from the discharge pollution degree detection unit 303 with the predetermined pollution standard. To generate a control signal. In this case, the output unit 306 displays both the result of comparing the pollution degree of the exhaust air with the preset pollution standard and the ratio of the exhaust air pollution degree to the intake air pollution degree.

The output selection unit 308 receives an output selection command from the function operation unit 82 when the user inputs an output selection command using the input button of the function operation unit 82.

Here, the output selection command means, for example, a command for selecting whether to output information relating to whether or not the pollution degree of the exhaust air is equal to or less than the preset pollution standard, or to output the ratio of the pollution degree of the exhaust air to the pollution degree of the intake air.

When the control unit 305 receives the output selection command from the output selection unit 308, the control unit 305 controls the output unit 306 according to the contents of the output selection command to determine whether or not the pollution degree of the exhaust air is equal to or less than the preset pollution standard. Optionally output the information or the ratio of the pollution degree of the exhaust air to the pollution degree of the inhaled air.

The diagnostic command receiver 309 receives a diagnostic command signal from the function operator 82 when a user inputs a diagnosis command using a button of the function operator 82.

When the diagnostic command signal is received from the diagnostic command receiver 309, the controller 305 controls the suction power of the vacuum cleaner 1 to be sequentially changed, and the control unit 305 controls the suction air according to the changed suction power. The rate of contamination is sequentially calculated and the information indicating the calculated rate is controlled through the output unit 306.

Here, the control unit 305 controls the output unit 306 to output information on the optimum suction force, which is the suction force at which the pollution degree of the exhaust air is equal to or less than the predetermined pollution standard and the ratio of the discharge air pollution degree to the suction air pollution degree is maximum. can do.

When a suction force selector 301 for selecting the intensity of the driving suction input of the vacuum cleaner 1 is included, the number of the diagnostic suction inputs that can be selected as the suction force at which the ratio of the discharge air pollution degree to the suction air pollution degree is maximum is selected. Is equal to the number of. For example, when the vacuum cleaner 1 selects the intensity of driving suction inputs such as strong, medium, and weak by using the user driving button 10, the three types of selectable diagnostic suction inputs are strong, medium, and weak. do.

If the vacuum cleaner 1 can be selected to continuously change the intensity of the driving suction input from the user driving button 10, the selectable intensity of the diagnostic suction input can be three, such as strong, medium, or weak, or compared to the maximum suction force. 50% suction power, 70% of the maximum suction power, such as the numerical value can be represented. That is, when the driving suction input is continuously changeable, the driving suction input may be continuously expressed as a ratio of the optimum suction force to the maximum suction force.

4 is a block diagram illustrating an air pollution information notification method according to the present embodiment.

Hereinafter, the air pollution information notification method according to the present embodiment will be described with reference to FIGS. 1B to 4.

When the user inputs an output selection command for selecting the discharge air pollution degree notification content of the vacuum cleaner 1 using the input button of the function control unit 82, the suction force selection unit 301 selects the output from the function operation unit 82. Receive a signal (S410). Herein, the pollution degree notification content means the ultra-fine dust concentration of the exhaust air, whether the pollution degree of the exhaust air is less than or equal to the preset pollution standard, or the ratio of the pollution degree of the exhaust air to the pollution degree of the inhaled air.

When the user selects the intensity of any one of the strong, medium, and weak driving suction inputs using the user driving button 10, the controller 305 may operate the motor 60 according to the driving suction input selected by the user driving button 10. Drive to generate a suction force (S420).

After the driving suction input is selected by the user driving button 10 and the suction force is generated, the suction pollution degree detecting unit 302 calculates the contamination level of the suction air detected by the step S430 and is detected by the discharge pollution degree detecting unit 303. The pollution degree of the exhaust air is calculated (S440).

Here, the output selection command receiving process (S410), the drive suction input selection process (S420), and the suction air pollution detection process (S430) can be omitted, it can be selectively employed according to the embodiment.

The controller 305 controls the output unit 306 to output the pollution-related information of the discharged air when calculating the output selection command, the intensity of the driving suction input, the pollution degree of the intake air, and the pollution degree of the discharged air (450). The pollution-related information of the exhaust air means the ultra-fine dust concentration of the exhaust air, whether the pollution of the exhaust air is less than or equal to the preset pollution standard, or the ratio of the pollution of the exhaust air to the pollution of the intake air.

As an example of the output of pollution-related information of the exhaust air, the output unit 306 is controlled by the control unit 305 in steps of the degree of concentration (eg, very bad, bad, normal, good) according to the ultra fine dust concentration. Step 4) can be displayed qualitatively, or ultra-fine dust concentration can be displayed at a specific value such as 15 μg / m 3.

In addition, as another example of the output of the pollution-related information of the exhaust air, the control unit 305 in step S450, the ratio of the exhaust air pollution degree to the intake air pollution degree using the intake air pollution degree related signal received from the intake pollution degree detection unit 302. Is displayed.

In addition, in step S450, the controller 305 controls the output unit 306 according to the content of the output selection command so as to determine whether the pollution degree of the exhaust air is less than or equal to a preset pollution standard, or the emission air pollution degree to the intake air pollution degree. Optionally output the ratio of.

5 is a block diagram illustrating an optimal suction force strength diagnostic method according to the present embodiment.

Hereinafter, the optimal suction force strength diagnosis method according to the present embodiment will be described with reference to FIGS. 1B to 4.

As shown in FIG. 5, when the user inputs power by operating the user driving button 10 to use the vacuum cleaner 1, the output unit 306 displays the diagnosis result stored in the internal memory ( S510). The diagnosis result stored in the internal memory of the vacuum cleaner 1 is the result stored as a result of the previous optimum suction force diagnosis.

The controller 305 controls the output unit 306 to output a message indicating that the diagnosis is not performed when the result of performing the optimal suction force strength diagnosis is not stored.

The control unit 305 continuously checks whether the user inputs a diagnostic command by using the button of the function operation unit 82 (S520).

The controller 305 continues to display a diagnosis result related message when the user does not input a diagnosis command. The diagnosis result related message may be a message indicating a result of a previous diagnosis or a message indicating that a diagnosis is not performed.

The control unit 305 controls the driving force of the motor 60 so that the suction force of the vacuum cleaner 1 is sequentially changed when receiving the diagnosis command signal from the diagnosis command receiving unit 309. For example, the controller 305 controls the driving force of the motor 60 to change in the order of weak, medium, or strong, or controls the change of the intake air pollution rate to the intake air pollution degree according to the changed suction force while controlling to change in the order of strong, medium, or weak. The ratio is calculated sequentially (S520).

In addition, when the vacuum cleaner 1 selects the intensity of the driving suction input continuously by the user driving button 10, the controller 305 is changed while changing the intensity of the driving suction input of the motor 60 continuously. According to the suction power, the ratio of the discharge air pollution to the intake air pollution can be expressed as continuous values such as 50% suction power and 70% suction power.

The controller 305 sequentially calculates the ratio of the discharge air pollution to the intake air pollution according to the intensity of the driving suction input, and then outputs the information indicating the suction force at which the ratio of the exhaust air pollution to the intake air pollution is maximum. In order to control the output through the control unit and store the diagnosis result in the internal memory (not shown) of the vacuum cleaner 1 (S540). In this case, the controller 305 may output the information indicating the suction force in which the ratio of the exhaust air pollution degree to the intake air pollution degree is maximum, so that the output is limited only when the pollution degree of the exhaust air is equal to or less than the predetermined pollution standard. .

As described above, in the case where the step S420 of selecting the driving suction input of the vacuum cleaner 1 is included, the driving suction input strength of the steel, medium, and the like is increased by using the user driving button 10 in the vacuum cleaner 1. If it is selectable, the intensity of the diagnostic suction input that can be selected as the optimum suction force is three types: strong, medium, and weak.

The optimal suction force selected as described above is stored in the internal memory (not shown) of the vacuum cleaner 1, and the output unit 306 reads the contents of the optimum suction force stored in the internal memory (not shown) and outputs the message as a message (S510).

The above description is merely illustrative of the technical idea of the present embodiment, and those skilled in the art to which the present embodiment belongs may make various modifications and changes without departing from the essential characteristics of the present embodiment. Therefore, the present embodiments are not intended to limit the technical idea of the present embodiment but to explain, and the scope of the technical idea of the present embodiment is not limited by these embodiments. The scope of protection of the present embodiment should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present embodiment.

1: vacuum cleaner
10: user drive button 20: inlet
32: intake contamination sensor 34: exhaust pollution sensor
40: dust bucket
52: first exhaust filter 54: second exhaust filter
56: third exhaust filter 58: fourth exhaust filter
60: motor 70: internal exhaust port
80: drive control unit 82: function control unit
90: outside air vent
301: suction power selection unit 302: suction contamination detection unit
303: emission pollution detection unit 305: control unit
306: output unit 307: motor drive unit
308: output selection unit 309: diagnostic command receiving unit

Claims (11)

In the vacuum cleaner which purifies the suction air by using the exhaust filter and discharges it,
An intake contamination detector for detecting a pollution level of the intake air;
An exhaust pollution detection unit for detecting a pollution degree of exhaust air discharged through the exhaust filter;
A controller configured to generate a control signal for outputting pollution degree related information of the exhaust air; And
A pollution information output unit configured to output the pollution degree related information according to the control signal; And
Diagnostic command receiving unit for receiving a diagnostic command from the user
Including but not limited to:
The pollution degree information is a ratio of the pollution degree of the exhaust air to the pollution degree of the intake air,
The controller controls the suction force of the vacuum cleaner to be sequentially changed, and sequentially calculates the ratio according to the change of the suction force to control the information related to the ratio to be output through the pollution information output unit. delete The method of claim 1,
And the control unit generates the control signal including a signal indicating a purification capability of the vacuum cleaner based on the ratio. The method of claim 1,
The control unit is a vacuum cleaner, characterized in that for generating the control signal including a signal indicating the result of comparing the pollution degree of the exhaust air with a predetermined pollution standard and the signal indicating the ratio. delete The method of claim 1,
The control unit is a vacuum cleaner, characterized in that for controlling so that the information indicating the optimal suction force, the suction power of the pollution degree is less than a predetermined pollution standard and the ratio is the maximum through the pollution information output unit. The method of claim 6,
Further comprising a suction force selection unit for selecting the drive suction input of the vacuum cleaner,
And the number of intensities selectable as the optimum suction force is the same as the number of intensities selectable by the driving suction input. The method of claim 6,
Further comprising a suction force selection unit for selecting the drive suction input of the vacuum cleaner,
And when the driving suction input is continuously changeable, the strength selectable as the optimum suction force is a ratio of the optimum suction force to the maximum suction force. In the vacuum cleaner which purifies the suction air by using the exhaust filter and discharges it,
An inhalation contamination detection process for sensing a pollution degree of the intake air;
Pollution degree detection process of the exhaust air for detecting the degree of pollution of the exhaust air discharged through the exhaust filter;
A control process of generating a control signal for outputting pollution degree related information of the exhaust air; And
A pollution information output process of outputting the pollution degree related information according to the control signal; And
Diagnostic process to receive diagnostic command from user
Including,
The pollution degree information is a ratio of the pollution degree of the exhaust air to the pollution degree of the intake air,
In the control process, the air pollution information notification method for controlling the diagnostic suction input of the vacuum cleaner to change sequentially, and calculates the ratio in accordance with the change of the diagnostic suction input to control to output the information associated with the ratio. delete delete

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