KR102124456B1 - Apparatus for managing of filter of air conditioner - Google Patents

Abstract

The present invention relates to a filter management device for an air conditioner. According to an embodiment of the present invention, the filter management device for an air conditioner includes: a body unit comprising a penetrated frame; a filter unit inserted into the body unit; a detection unit for detecting indoor fine dust information at a preset time period; and a control unit for outputting a replacement signal for the filter unit when the fine dust information exceeds preset reference concentration. Accordingly, the replacement time of an air conditioner filter is notified based on concentration of indoor fine dust.

Description

Filter management device for air conditioner{APPARATUS FOR MANAGING OF FILTER OF AIR CONDITIONER}

The present invention relates to a filter management device for an air conditioner, and more particularly, a technique for managing a replacement time of an air conditioner according to a fine dust concentration in a room is disclosed.

Recently, interest in indoor air quality (IA) has increased. This interest was initially sparked by reports of residents of various indoor environments complaining about unspecified symptoms such as irritation or dryness of the mucous membrane, burning eyes, and headaches from fatigue. In some cases, these symptoms can be related to high concentrations of certain pollutants in the indoor air, such as formaldehyde, so that whenever people complain about bad indoor air quality, they measure the pollutants in the climatic conditions and indoor air. Interest in making decisions.

Among the conventional technologies, Korean Patent Registration No. 10-1591735 (announced on February 11, 2016) relates to a method of providing pollutant information through prediction of indoor air quality, and a sensor device that measures pollutants according to various types of pollutants Based on the measurement data generated from the information, it predicts the concentration of pollutants, provides information, and predicts the expected air purification when applying the air purification capability of the air purification device installed in a large building to the current indoor air pollution. It is a technical feature that can actively manage the indoor air quality of large buildings by providing.

However, the prior art has limitations in managing the replacement time of the filter. In other words, the air purification ability may vary depending on how much contaminants are accumulated in the air conditioner filter. Accordingly, there is a need for a technology capable of determining when to replace the filter of the air conditioner and notifying the user.

The technical problem to be solved of the present invention is to provide a filter management device for an air conditioner that can notify the replacement point of the air conditioner filter based on the indoor fine dust concentration.

In addition, the present invention is to provide a filter management device for an air conditioner that can notify a more accurate time of filter replacement according to the wind speed or air flow rate of the air sucked into the air conditioner.

In addition, it is to provide a filter management device for an air conditioner that can notify the replacement time of a more accurate filter according to the light transmission amount of the air conditioner filter.

In addition, it is to provide a filter management device for an air conditioner that can notify the replacement point of a more accurate filter according to the weight of the air conditioner filter.

In addition, it is to provide a filter management device for an air conditioner that can more accurately grasp the indoor occupancy information and optimize the operation of the air conditioner.

The filter management device for an air conditioner according to an embodiment of the present invention includes a main body part formed of a perforated frame, a filter part inserted in the main body part, a sensing part for detecting fine dust information in the room at a predetermined time period, And a control unit outputting a replacement signal for the filter unit when the fine dust information exceeds a preset reference concentration.

In addition, the filter unit may include a mesh filter inserted into the main body, and an antibacterial filter coated with an antibacterial component and adhered to one surface of the mesh filter.

In addition, the sensing unit detects the fine dust information and the blowing information sucked through the filter unit, and the control unit receives the replacement signal when the fine dust information is within the reference concentration and the blowing information is less than a preset reference blow. Can print

In addition, the sensing unit detects the light emission amount information by irradiating the fine dust information and the filter unit, and the control unit has the fine dust information within the reference concentration, and the light emission information is less than a preset reference light emission amount. In this case, the replacement signal may be output.

In addition, the sensing unit detects the weight information by measuring the weight of the fine dust information and the filter unit, and the controller detects if the fine dust information is within the reference concentration and the weight information exceeds a preset reference weight. A replacement signal can be output.

Accordingly, it is possible to notify the replacement time of the air conditioner filter based on the indoor fine dust concentration.

In addition, it is possible to notify the timing of replacement of the filter more accurately according to the wind speed or air volume of the air sucked into the air conditioner.

In addition, it is possible to notify the replacement time of a more accurate filter according to the light transmission amount of the air conditioner filter.

In addition, according to the weight of the air conditioner filter, a more accurate filter replacement time can be notified.

In addition, it is possible to more accurately grasp the indoor occupancy information to optimize the operation of the air conditioner.

1 is a block diagram of a filter management device for an air conditioner according to an embodiment of the present invention.
FIG. 2 is a cross-sectional configuration diagram of a filter part of the filter management device for an air conditioner according to FIG. 1.
3 is a detailed configuration diagram of an antibacterial filter among the filter units according to FIG. 2.
FIG. 4 is an exemplary view for explaining generation of fine dust information in a detection unit of the filter management device for an air conditioner according to FIG. 1.
5 is a detailed configuration diagram of the detection unit of the filter management device for an air conditioner according to FIG. 1.
6 is an exemplary view for explaining that a cleaning unit is added to the filter management device for an air conditioner according to FIG. 1.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The terms used are terms selected in consideration of functions in an embodiment, and the meaning of the terms may be changed according to a user's or operator's intention or precedent. Therefore, the meaning of the terms used in the embodiments described below, if specifically defined in this specification, will follow the definition, and if there is no specific definition, it should be interpreted as a meaning generally recognized by those skilled in the art.

1 is a block diagram of a filter management device for an air conditioner according to an embodiment of the present invention.

Referring to FIG. 1, the filter management device 100 for an air conditioner according to an embodiment of the present invention includes a body unit 110, a filter unit 120, a sensing unit 130, and a control unit 140.

The body portion 110 is formed of a frame of a rectangular structure penetrated. The body portion 110 is formed in a closed structure on one side by a cover. The filter part 120 to be described later is inserted into the space penetrated inside the body part 110. In this case, the main body 110 may be formed with a plurality of stepped jaws for fixing the filter unit 120 on the inner surface. The body portion 110 may be changed in shape depending on the shape of the air conditioner. The main body 110 may be formed in a ceiling-mounted type or a stand-type type, but is not limited thereto.

The filter unit 120 is inserted into the body unit 110 to remove dust in the inhaled air. The filter unit 120 may be formed in various structures to remove fine dust and the like. The filter unit 120 is detachably coupled to the body unit 110. The filter unit 120 can be replaced after being used for a certain period of time. Specifically, the filter unit 120 includes a mesh filter 121 and an antibacterial filter 122. The mesh filter 121 is a primary filter that is formed in a wire mesh form and filters foreign substances. At least one mesh filter 121 may be inserted into the main body 110. The antibacterial filter 122 is bonded to one surface of the mesh filter 121 in the form of a film coated with an antibacterial substance. In this case, air passing through the mesh filter 121 passes through the antibacterial filter 122 to remove bacteria.

The sensing unit 130 detects indoor fine dust information at a preset time period. The sensing unit 130 may be formed inside or outside the main body 110 or may be remotely spaced. The sensing unit 130 acquires the concentration of indoor fine dust at a preset time period. The sensing unit 130 outputs the obtained fine dust information to the control unit 140. The fine dust information is used as information for determining how much fine dust in the room is being removed. For example, when the air conditioner operates, it may be determined that the function of the filter unit 120 is deteriorated when the indoor fine dust information exceeds a preset reference concentration.

In addition, the sensing unit 130 may sense blowing information sucked through the filter unit 120. In the blowing information, the more the foreign material is adsorbed on the filter unit 120, the lower the wind speed or air volume is. When the air is sucked, the sensing unit 130 acquires the blowing information and outputs it to the control unit 140. The blowing information is used as information for determining the replacement cycle of the filter unit 120. For example, when the blowing information is less than a preset reference blowing, it may be determined that the function of the filter unit 120 is deteriorated. Accordingly, a replacement signal of the more accurate filter unit 120 can be generated.

In addition, the sensing unit 130 may detect the amount of light emitted by irradiating the filter unit 120 with illumination. The light transmittance information decreases as the foreign matter is adsorbed on the filter unit 120. In this case, the sensing unit 130 is formed with a light emitting unit 133-1 and a light receiving unit 133-2 for outputting light with the filter unit 120 interposed therebetween, and is irradiated through the light emitting unit 133-1. It detects how much light passes through the filter unit 120 to reach the light receiving unit 133-2. The sensing unit 130 outputs the light emission amount information to the control unit 140. The light emission amount information is used as information for determining the replacement cycle of the filter unit 120. For example, when the light transmission amount information is less than a preset light transmission amount, it may be determined that the function of the filter unit 120 is deteriorated. Accordingly, a replacement signal of the more accurate filter unit 120 can be generated.

In addition, the sensing unit 130 may detect weight information by measuring the weight of the filter unit 120. The weight information detects the excess weight in addition to the basic weight of the filter. In this case, the sensing unit 130 may be formed in the form of a load cell to measure the weight of the filter unit 120. The sensing unit 130 generates weight information at a preset time period and outputs the weight information to the control unit 140. The weight information is used as information for determining the replacement cycle of the filter unit 120. For example, when the weight information exceeds the preset weight information, it may be determined that the function of the filter unit 120 is deteriorated. Accordingly, a replacement signal of the more accurate filter unit 120 can be generated.

Also, the sensing unit 130 may collect indoor gas information. In this case, the sensing unit 130 may collect gas information such as carbon dioxide and formaldehyde in the room in addition to the fine dust information. The indoor gas information is collected through the sensor 130 to be used as information for changing the indoor ventilation cycle or the driving cycle of the air conditioner. The sensing unit 130 may also subdivide various gas information and output it to the control unit 140. In addition to being formed inside the body portion 110, the detector 130 may be formed to be spaced apart from the body portion 110.

The control unit 140 outputs a replacement signal for the filter unit 120 when the fine dust information exceeds a preset reference concentration. The control unit 140 determines the rate of change by collecting fine dust information from the detection unit 130 at a preset time period. The control unit 140 outputs a replacement signal through a speaker or LED when the indoor fine dust exceeds a preset reference concentration despite the operation of the air conditioner. This is to allow the user to replace the filter unit 120 to improve indoor air quality by warning that the fine dust in the room is not filtered by the filter unit 120.

In addition, even when the fine dust information is within a preset reference concentration, the control unit 140 may output a replacement signal when at least one of the blowing information, the light emission amount information, and the weight information is outside the allowable value. For example, when the blowing information is less than the reference blowing, the control unit 140 may determine that the air circulation is not properly performed by foreign substances and output a replacement signal.

In addition, the control unit 140 may reset the replacement cycle of the filter unit 120 by analyzing the change amount of the blowing information of the detection unit 130. For example, during a certain period of time, the air pressure and the air volume among the blowing information for the filter unit 120 are gradually reduced, and if the air pressure and the air volume suddenly increase, it is determined that the filter unit 120 is damaged and outputs an emergency replacement signal. It is possible. This may generate a replacement signal when the membrane portion antibacterial filter 122 is perforated by wind pressure or the like when the filter unit 120 is implemented as a mesh Peter 121 and an antibacterial filter 122.

Also, the control unit 140 may determine that the filter unit 120 is contaminated or has a foreign substance formed even when the light emission amount information is less than the reference light emission amount, and outputs a replacement signal. The control unit 140 may also measure the fine dust concentration by determining the light emission amount information at a predetermined time period. This is to set the replacement timing by comparing the fine dust concentration in the air with the fine dust concentration on the filter unit 120.

In addition, the control unit 140 may determine that the weight of the filter unit 120 is increased due to fine dust or the like when the weight information exceeds the reference weight, and output a replacement signal of the filter unit 120. Accordingly, in addition to the fine dust information, it is possible to generate a more accurate filter replacement cycle by using blowing information, light emission amount information, and weight information.

In addition, the control unit 140 may output a replacement signal in anticipation of the replacement cycle of the filter unit 120. The control unit 140 may determine a replacement cycle by calculating a time when the filter unit 120 is replaced. For example, the average of the replacement periods of the plurality of filter units 120 may be calculated to output a replacement signal when the average replacement period of the filter unit 120 approaches. In this case, the control unit 140 may output a replacement signal even when the fine dust information is within a reference concentration. This is to prevent the case where the fine dust information is normal, even if the filter unit 120 is replaced, or if the antibacterial performance deteriorates or contaminants such as mold remain.

In addition, the control unit 140 may control the driving conditions of the air conditioner using the fine dust information or gas information of the detection unit 130. For example, when the fine dust information exceeds the safety range, but the gas information is within the safety range, the air conditioner is controlled in the blowing mode to filter the fine dust through the filter unit 120. However, if the fine dust information is within the safety range or the gas information exceeds the safety range, ventilation may be induced through an indoor window by notifying the LED. This reflects various environmental indicators, and you can choose to actively run the air conditioner or stop the air conditioner and open the window. In this case, the safety range is a range set based on the data learned at a constant time period.

Meanwhile, the filter management device 100 for an air conditioner according to an embodiment of the present invention may further include a communication unit 150. The communication unit 150 communicates with an external user terminal 10. The communication unit 150 can also communicate with an external server. The control unit 140 transmits fine dust information or a replacement signal to the user terminal 10. The control unit 140 may transmit fine dust information and a replacement signal to the external user terminal 10 together with the location information where the filter unit 120 is installed. Accordingly, the user can confirm the indoor fine dust information or the replacement signal of the filter unit 120 even remotely.

In addition, the communication unit 150 may be formed in the form of an electronic tag 151 on one surface of the filter unit 120. In the electronic tag 151, identification information including a manufacturing date, model number, and manufacturer of the corresponding filter unit 120 is encrypted. For example, the electronic tag 151 is preferably formed on the antibacterial filter 122 of the filter unit 120. This is because the antibacterial filter 122 is replaced after a certain period of time. The electronic tag 151 may be RF communication, NFC communication, or the like. When the user identifies the electronic tag 151 through the user terminal 10 to the filter, the user can check the replacement timing of the corresponding filter unit 120. In this case, it is preferable that an application capable of identifying the electronic tag 151 is installed in the user terminal 10.

FIG. 2 is a cross-sectional view of the filter portion of the filter management device for an air conditioner according to FIG. 1, and FIG. 3 is a detailed configuration diagram of an antibacterial filter in the filter portion according to FIG. 2.

2 and 3, the filter unit 120 of the filter management apparatus for an air conditioner of the present invention includes a mesh filter 121 and an antibacterial filter 122. In this case, the antibacterial filter 122 may be composed of a first antibacterial block 122-1 and a second antibacterial block 122-2. The first antibacterial block 122-1 and the second antibacterial block 122-2 are blocks of a nonwoven fabric impregnated with or coated with antibacterial components, respectively. The plurality of first antibacterial blocks 122-1 are arranged spaced apart from each other on the same plane. The air permeability of the first antibacterial block 122-1 may vary depending on the compressed density or material. The plurality of second antibacterial blocks 122-2 are arranged spaced apart from each other on the same plane. In this case, the second antibacterial block 122-2 is stacked and arranged at a position corresponding to the spaced apart space of the first antibacterial block 122-1. The first antibacterial block 122-1 and the second antibacterial block 122-2 are connected to each other by a certain couple.

The air passing through the mesh filter 121 directly passes through the first antibacterial block 122-1 or moves between spaces spaced between the plurality of first antibacterial blocks 122-1. The air that has passed through the first antibacterial block 122-1 passes through the second antibacterial block 122-2. Accordingly, the air passing through the mesh feeder may increase the removal rate of bacteria while passing through the first antibacterial block 122-1 and the second antibacterial block 122-2. In addition, while moving between the spaced apart space between the first antibacterial block 122-1 and the spaced apart space between the second antibacterial block 122-2, the contact surface between the first antibacterial block 122-1 widens, resulting in fine dust or dirt. It is possible to maximize the effectiveness of filtering contaminants such as bacteria. The density or material of the first antibacterial block 122-1 and the second antibacterial block 122-2 may be different. The first antibacterial block 122-1 and the second antibacterial block 122-2 may be laminated by bonding to each other. The first antibacterial block 122-1 and the second antibacterial block 122-2 may be additionally stacked according to a user's setting.

FIG. 4 is an exemplary view for explaining generation of fine dust information in a detection unit of the filter management device for an air conditioner according to FIG. 1.

Referring to FIG. 4, the sensing unit 130 of the filter management device for the air conditioner of the present invention may be formed integrally with the main body 110 or separated from the main body 110. When the sensing unit 130 is formed as an independent module, it is possible to communicate with the main unit 110 or the user terminal 10 through a network. The sensing unit 130 generates fine dust information for the accumulated fine dust concentration at a preset time period and transmits the fine dust information to the control unit 140. The control unit 140 may collect fine dust information and transmit it to the user terminal 10. The user terminal 10 may display fine dust information including the current fine dust concentration, and information about a usage time and an estimated replacement time after replacement of the filter unit 120. Accordingly, the user can be guided to the indoor fine dust information and the replacement point of the filter unit 120.

5 is a detailed configuration diagram of the detection unit of the filter management device for an air conditioner according to FIG. 1.

Referring to FIG. 5, among the filter management devices for an air conditioner of the present invention, the sensing unit 130 may include at least one of a fine dust sensor 131, an air flow sensor 132, a light emitting sensor 133, and a weight sensor 134. It can contain. For example, the fine dust sensor 131 may detect fine dust of the inhaled air using infrared rays. The air flow sensor 132 measures wind speed or wind pressure of the inhaled air. In the light emitting sensor 133, a light emitting unit 133-1 is located on one side of the filter unit 120, and a light receiving unit 133-2 is located on the other side of the filter unit 120. The light-transmitting sensor 133 can detect the contamination of the filter unit 120 itself, by how much the light irradiated from the light-emitting unit 133-1 reaches the light-receiving unit 133-2, by a refractive index, or the like. The weight sensor 134 detects a change in weight of the filter unit 120, and its position may vary depending on the installation position of the filter unit 120. The weight sensor 134 may be formed in plural according to the size of the filter unit 120.

Referring back to FIG. 1, the filter management device 100 for an air conditioner according to an embodiment of the present invention may further include an image acquisition unit 160. The image acquisition unit 160 may acquire images on one or both sides of the filter unit 120. The image acquisition unit 160 may be implemented as a shooting module capable of close-up photography. The image acquisition unit 160 may acquire an image of the surface of the filter unit 120 at a predetermined time period. The image acquisition unit 160 outputs the acquired image information to the control unit 140. The control unit 140 may determine the degree of contamination through binary data processing of the captured image information. The control unit 140 may determine the contaminated location and the degree of contamination through a vision inspection of the filter unit 120. In addition, the control unit 140 may transmit image information on the filter unit 120 to the user terminal 10 so that the user can visually check the status of the filter unit 120. Accordingly, it is possible to more accurately determine the replacement point of the filter unit 120 through the vision inspection.

Also, the image acquisition unit 160 may acquire indoor images to generate occupancy information. The image acquisition unit 160 may acquire an image of an indoor space in addition to the image of the filter unit 120 using a plurality of cameras. This is to determine how many users are indoors using the room information. The image acquisition unit 160 acquires the presence information and outputs it to the control unit 140. In this case, the control unit 140 generates the first occupancy information based on the gas information obtained through the sensing unit 130 and generates second occupancy information by analyzing the image information of the image acquisition unit 160. The control unit 140 compares the first occupancy information and the second occupancy information and controls the operation of the air conditioner based on the first occupancy information when it is within a preset value. When the first occupancy information and the second occupancy information exceed a preset value, the controller 140 may control the operation of the air conditioner based on the second occupancy information.

As described above, the filter management device for the air conditioner according to the exemplary embodiment of the present invention can provide optimal cooling and heating loads while minimizing power by controlling the operation state of the air conditioner using room information. In addition, it is possible to more accurately grasp the number of indoor users to control heating and cooling.

6 is an exemplary view for explaining that a cleaning unit is added to the filter management device for an air conditioner according to FIG. 1.

Referring to FIG. 6, a filter management device for an air conditioner according to an embodiment of the present invention may further include a cleaning unit 170. The cleaning unit 170 may be filled with an antibacterial cleaning solution therein. In the washing unit 170, a plurality of tubes 171 in the form of capillaries are connected to the filter unit 120 to transfer the washing liquid through the discharge hole 172. Specifically, the cleaning solution is supplied to the antibacterial filter 122 among the filter units 120. When the washing unit 170 is pressed, the washing liquid is moved to the filter unit 120 through the tube 171. Before an external force is applied to the washing unit 170, the washing liquid does not move to the tube 171 due to a pressure difference. When the cleaning liquid is absorbed by the filter unit 120, the cleaning liquid applied to the filter unit 120 is evaporated by the inhaled air and then recharged to maximize the cleaning effect. In this case, an injection hole 173 is formed on one side of the washing unit 170 to fill and use the washing liquid.

In the above, the present invention has been described with reference to preferred embodiments described with reference to the drawings, but is not limited thereto. Therefore, the present invention should be interpreted by the description of the claims intended to cover the obvious variations that can be derived from the described examples.

100: air conditioner filter management device
110: main body
120: filter unit
121: mesh filter
122: antibacterial filter
122-1: First antibacterial block
122-2: second antibacterial block
130: detection unit
131: fine dust sensor
132: air flow sensor
133: flood sensor
133-1: Light emitting section
133-2: Receiver
134: Weight sensor
140: control unit
150: communication unit
151: electronic tag
160: image acquisition department
170: cleaning unit
171: tube
172: vent hole
173: inlet

Claims (5)

A body portion formed of a pierced frame;
A filter part inserted into the main body part to remove fine dust, and a mesh filter inserted into the main body part and an antibacterial filter coated with an antimicrobial component and adhered to one surface of the mesh filter to be replaced;
An antimicrobial cleaning solution is filled through an inlet, and a cleaning unit for supplying the cleaning solution to the antibacterial filter through a discharge hole of a plurality of tubes connected to the antibacterial filter when pressurized;
A sensing unit configured to detect fine dust information in the room accumulated at a preset time period, blowing information sucked through the filter unit, and weight information of the filter unit;
An image acquisition unit that acquires an image of the surface of the filter unit at a preset time period;
Formed in the form of an electronic tag in the filter unit, the identification information including the manufacturing date, model number, and manufacturer of the filter unit is encrypted, and when the electronic tag is identified by an external user terminal, the replacement time of the filter unit can be checked. A communication unit for communicating; And
Determines the rate of change of the fine dust information, and when the fine dust information exceeds the preset reference concentration even in the operation of the air conditioner, transmits the location information, fine dust information, and replacement signal of the filter unit to the user terminal, and the fine dust When the information is within the reference concentration, and the blowing information is less than a preset reference blowing, or when the weight information exceeds a preset reference weight, the replacement signal is output, and image information for the filter unit is acquired to obtain vision. A filter management device for an air conditioner including a control unit for determining the location and degree of contamination by inspection. delete delete According to claim 1,
The sensing unit,
Illuminating the fine dust information and the filter unit to detect light emission information,
The control unit,
A filter management device for an air conditioner that outputs the replacement signal when the fine dust information is within the reference concentration and the light emission amount information is less than a preset reference light emission amount. delete

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