KR20100089605A - Method of determining exchange time of aircleaner filter - Google Patents

Abstract

PURPOSE: A method is provided to determine the replacement time of the filter of an air cleaner and accurately calculate the lifespan of each filter. CONSTITUTION: A replacement time calculating method comprises following steps. An air volume factor is determined based on the air volume of the air which passes through a filter. A pollution level factor is determined based on the pollution level of the air which passes through the filter. The present lifespan of the filter is determined by calculating the air volume factor and the pollution level factor for the operation time. The air volume factor is determined to a large value as the air volume is large. As the pollution level is large, the pollution level factor is determined to a large value. The filter is a HEPA filter eliminating the dust. The pollution level is the dust pollution level. The filter is the deodorization filter eliminating smell. The pollution level is the smell pollution level.

Description

Calculation method of exchange time of filter of air cleaner {METHOD OF DETERMINING EXCHANGE TIME OF AIRCLEANER FILTER}

The present invention relates to a method for calculating an exchange time of a filter of an air purifier.

In general, the air purifier may be referred to as a sanitary device that filters contaminants or fine dust when the contaminated air passes through the filter in the process of forcibly circulating the indoor air by blowing and discharges only the clean air to the room.

Therefore, it can be said whether the effective performance of the air purifier is determined by the degree of contamination of the filter, and it is important to extend the life of the device or to keep the indoor air clean by appropriately changing the filter. It becomes a point of view.

Korean Patent Laid-Open Publication No. 2003-0023891 discloses a method for displaying and detecting an exchange cycle of an air purifier filter, which measures the rotational speed of a motor shaft and detects a change in the rotational speed to indirectly measure the remaining life of the filter, and calculates the measured value to calculate the current lifetime. And a content of displaying the life limit value externally.

By the way, the air purifier is usually provided with a plurality of filters according to the purpose, such as functional filters, and the replacement time of each filter must be different, as described above. It is problematic to estimate the timing of replacement of the same, and as a result, the user cannot be informed of an appropriate replacement time for each filter, and thus the purpose of extending the life of the device or keeping the air clean cannot be achieved.

The present invention is designed to solve the problems of the prior art, and to provide a method for accurately calculating the replacement time of each filter in accordance with the environmental situation in consideration of the elements suitable for each filter of the air purifier.

According to a first aspect of the present invention for achieving the above object, in the method for calculating the replacement time of the filter of the air purifier, determining the air volume factor based on the air volume of the air passing through the filter, the filter Determining a pollution factor based on the pollution degree of the air passing through; and determining the current life of the filter by integrating the air volume factor and the pollution factor over an operating time; To provide.

According to the second aspect of the present invention, the air volume factor is determined as a larger value as the air volume is larger, and the pollution degree factor is determined as a larger value as the pollution degree is larger.

According to a third aspect of the invention, the filter is a hepa filter for removing dust, and the pollution degree is a dust pollution degree.

According to a fourth aspect of the invention, the filter is a deodorizing filter for removing odors, and the pollution degree is an odor pollution degree.

According to a fifth aspect of the present invention, the filter includes a hepa filter for removing dust and a deodorization filter for removing odor, and the pollution degree includes dust pollution and odor pollution, and the dust pollution degree with respect to the hepa filter. The contamination factor is determined on the basis of the deodorizing filter, and the contamination factor is determined on the basis of the odor contamination level of the deodorizing filter, and the current lifetimes of the hepa filter and the deodorizing filter are respectively determined.

According to a sixth aspect of the invention, there is further included the step of determining the remaining life of the filter by subtracting the current life of the filter from the limit life of the filter.

According to a seventh aspect of the invention, the current life of the filter or the remaining life of the filter is displayed on the display of the air cleaner.

According to the present invention, the air volume and the dust pollution degree are taken into consideration when calculating the replacement time of the hepa filter for removing dust, and the air volume and the smell pollution degree are considered when calculating the replacement time of the deodorizing filter for removing the odor. The timing of replacement can be accurately calculated for each filter.

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

1 is an exploded perspective view of an air cleaner according to an embodiment of the present invention, Figure 2 is a side cross-sectional view of the air cleaner according to an embodiment of the present invention.

1 and 2, the air cleaner 100 includes a body 120 and a filter 140.

Body portion 120 forms the appearance of the air cleaner 100, the front cover 122 is formed on the front of the body portion 120 is formed with the inlet 124 for sucking the indoor air, the body portion 120 The upper portion of the discharge port 126 through which the purified air is discharged is formed.

The body part 120 is provided with a filter accommodating part 130 in which the filter part 140 is mounted, and a fan accommodating part in which the air blowing fan 132 for sucking the indoor air by the rotational force and discharging the purified air back into the room is installed. 134 is formed.

In addition, the body portion 120 is attached with a pollution detection sensor (not shown) for measuring the pollution of indoor air. The contamination sensor may include a dust sensor that measures dust pollution and a gas sensor that measures odor contamination. The dust sensor and the gas sensor are connected to a controller to be described later, and configured to control the air cleaner 100 according to the measured pollution degree.

The filter unit 140 includes a plurality of filters, and the sucked indoor air is purified while passing through the filter unit 140. The filter unit 140 may include a pre-filter 142, a medium filter 144, an AC (activated carbon) deodorization filter 146, and a hepa filter 148.

The prefilter 142 may be configured using an antibacterial material, and may remove relatively large dust, mold, hair, pet hair, and the like. The medium filter 144 may be configured using an antibacterial material, and may remove medium dust, pet hair, and the like. In addition, the pre-filter 142 and the medium filter 144 is not limited to the above-described filter may be formed of a combination of various filters. At least one of the prefilter 142 and the medium filter 144 may be configured as a functional filter such as a yellow dust filter, an infant-only filter, a birdhouse-only filter, and a collector-only filter.

The deodorizing filter 146 is a coal or coconut shell deodorizing filter that functions to adsorb and remove tobacco smoke, volatile organic compounds, and other odorous substances.

The HEPA filter 148 may cleanly remove up to 99% of harmful substances such as harmful house dust, mites, viruses, molds, and contaminants of 0.3 micron in size and particles contained in the incoming indoor air.

The blower fan 132 uses a centrifugal blower to which a sirocco fan (multi-blade fan) is applied, and air is sucked into the front suction port 124 and discharged to the upper discharge port 126. The discharge port 126 may be provided with a fine grid-shaped discharge grille so as not to enter the fingers of the infant.

Air flow control method of the air cleaner 100 configured as described above is as follows.

The air cleaner 100 may operate in a manual mode or an automatic mode according to a user's selection.

In the manual mode, the air is discharged at the air volume selected by the user regardless of the air pollution.

In the automatic mode, the air volume is controlled to be set according to the air pollution. That is, the dust sensor and the gas sensor respectively measure the dust pollution and odor pollution degree and send the measured value to the controller (not shown), and the controller determines the air volume based on the dust pollution and odor pollution degree received from each sensor. The air volume is determined so that a large amount of clean air is discharged as the air pollution degree is high. For example, when the air pollution is measured in 1 to 4 stages and the air volume is controlled in 1 to 4 stages, if the pollution degree is 1 stage, the air volume is determined as 1 stage, and when the pollution degree is 3 stages, the air volume is determined as 3 stages. It is.

On the other hand, when the dust pollution and odor pollution degree is different, the air volume is determined based on the pollution degree having a high pollution degree. For example, if the dust pollution degree is one stage but the odor pollution degree is three stages, the pollution degree is determined as three stages, and accordingly, the air flow rate is three stages (see FIG. 3). On the contrary, when the dust pollution degree is higher than the odor pollution degree, the air volume is determined according to the dust pollution degree. Thus, by setting the air volume on the basis of the high pollution degree, it is possible to achieve rapid air purification.

Next, a method for calculating replacement time of each filter in the air cleaner 100 operating as described above will be described.

As shown in FIG. 3, if the dust pollution degree is one stage and the odor pollution degree is three stages, the air volume is determined to be three stages. By the way, when the air volume is operated in three stages, the load of each filter according to the air volume is the same, but the load of each filter according to the pollution degree is different. For example, since the HEPA filter 148 functions to remove fine dust, the load on the HEPA filter 148 increases as the degree of dust contamination increases, and the deodorization filter 146 functions to remove odorous substances. The higher the load on the deodorization filter 146 increases. Therefore, in the example of FIG. 3, although the wind of the same intensity passes through the HEPA filter 148 and the deodorization filter 146, the load applied to the deodorization filter 146 because the odor contamination degree is higher than the dust pollution degree is the HEPA filter 148. If the load is greater than the load applied to the load, and the state persists, the performance deterioration of the deodorization filter 146 proceeds faster than the performance deterioration of the hepa filter 148. In this way, each filter is subjected to the same load by the amount of air passing through the filter, but differs depending on the pollution degree corresponding to each filter.

On the other hand, the load on the filter accumulates with time, and the filter is at the end of its service life and replacement is desired.

Taken together, to calculate the current life of the filter, the airflow factor and the pollution factor corresponding to the filter must be taken into account and integrated according to the operating time. Expressed as an expression:

Current life of filter = Σ (airflow factor + pollution factor corresponding to filter) × operating time

According to the above equation, the current lifetime of the HEPA filter 148 and the deodorization filter 146 is calculated as follows.

H _life = Σ (Q _f + D _f ) × T

A _life = Σ (Q _f + G _f ) × T

(Where H _life is the current _life of the HEPA filter, A _life is the current _life of the deodorizing filter, Q _f is the air volume factor, D _f is the dust pollution factor, G _f is the odor pollution factor, and T is the operating time.)

Referring to the example illustrated in FIG. 3, since the dust pollution degree is one stage, the odor pollution degree is three stages and the air volume is three stages, D _f may be 1, G _f is 3, and Q _f may be 3. If you operate for 3 hours in this state, T is 3. Now, substituting this parameter into the above equation, the current life (H _life ) of the HEPA filter is 12, and the current life (A _life ) of the deodorization filter is 18. If the limit lifetime of the two filters is 100, the remaining life of the HEPA filter is 88 and the remaining life of the deodorization filter is 82. Thus, although the same air volume was applied to each filter, it turns out that the load on each filter is different, and accordingly, the remaining lifetime is also calculated differently.

The present or remaining life of each filter can be displayed on the display of the air cleaner 100 so that the user can recognize it and predict the replacement time.

In the above example, D _f is assumed to be 1 when the dust pollution degree is one stage, but D _f is expressed as a function of dust pollution degree, and the larger the dust pollution degree is, the larger the value is. Similarly, G _f is expressed as a function of odor contamination and the larger the odor contamination, the larger the value. Q _f is a function of the air volume and is determined to be larger as the air volume is larger.

In addition, in the above example, only the HEPA filter and the deodorization filter have been described. However, the filter replacement time can be calculated for the prefilter and the medium filter by determining the contamination factor according to the characteristics of each filter.

As described above, according to the filter life estimation method of the present invention, since not only the air volume but also the pollution degree corresponding to each filter is taken into consideration, it is possible to calculate the exact filter life of each filter.

1 is an exploded perspective view of an air cleaner according to an embodiment of the present invention.

2 is a side cross-sectional view of an air cleaner according to an embodiment of the present invention.

3 is a diagram showing a control state of the air volume according to the pollution degree of the indoor air.

Explanation of symbols on the main parts of the drawings

100 Air Purifier 120 Body

124 inlet 126 outlet

140 Filter section 146 Deodorization filter

148 hepa filter

Claims (7)

In the method of calculating the exchange time of the filter of the air cleaner, Determining a flow rate factor based on the flow rate of air passing through the filter, Determining a pollution factor based on the pollution of air passing through the filter, and And determining the current life of the filter by integrating the air volume factor and the pollution factor with respect to an operating time. The method according to claim 1, The air volume factor is determined by a larger value as the air volume is larger, And the pollution factor is determined by a larger value as the pollution degree is greater. The method according to claim 1 or 2, The filter is a hepa filter for removing dust, And said pollution degree is a dust pollution degree. The method according to claim 1 or 2, The filter is a deodorization filter to remove odors, And the pollution degree is an odor pollution degree. The method according to claim 1 or 2, The filter includes a hepa filter for removing dust and a deodorization filter for removing odors, The pollution degree includes dust pollution and odor pollution, Regarding the HEPA filter, a pollution factor is determined based on the dust pollution degree, Regarding the deodorization filter, the pollution factor is determined based on the odor pollution degree, And a current lifetime of each of the hepa filter and the deodorization filter is determined. The method according to claim 1 or 2, And determining the remaining life of the filter by subtracting the current life of the filter from the limit life of the filter. The method according to claim 6, A filter replacement time calculation method, characterized by displaying the current life of the filter or the remaining life of the filter on the display of the air cleaner.

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