KR102637762B1 - Air conditioner with cleaning function - Google Patents

Abstract

The present invention relates to an air conditioner equipped with a cleaning function. To be described in more detail, it is configured to suck in indoor air from a large-scale building, mix it with outdoor air, filter and cool it, and then supply it to the room. Disclosed is a technical field related to an air conditioner equipped with a cleaning function, which includes a component having a cleaning function in an air conditioning/heating unit.

Description

Air conditioner with cleaning function

The present invention relates to an air conditioner equipped with a cleaning function. To be described in more detail, it is configured to suck in indoor air from a large-scale building, mix it with outdoor air, filter and cool it, and then supply it to the room. It relates to an air conditioner equipped with a cleaning function that includes a component having a cleaning function in the cooling and heating unit.

In general, air conditioners are installed in buildings, such as in machine rooms, to condition the indoor air of each room. Air conditioners supply cooling or heating to the interior of a building or adjust the air in response to necessary indoor conditions, such as adjusting humidity and adding insect repellent. It has the function of

To elaborate, an air conditioner sucks in polluted indoor air, discharges about 30% of it to the outside, takes in as much outside air as the discharged indoor air, mixes it, adjusts it to an appropriate temperature through a heat exchange means, and then uses a filtering means. The cleanliness of indoor air is maintained by removing pollutants and supplying them indoors.

Recently, much research has been conducted on air conditioners with various functions to supply cleaner air indoors, and one of the technologies for such air conditioners is Publication Patent Publication No. 10-2018-0094158 (hereinafter referred to as ' (referred to as ‘prior art’) has been disclosed.

The prior art is intended to improve indoor air quality by deodorizing bad odors contained in indoor air, and is characterized by purifying indoor air using a photocatalytic filter.

Meanwhile, in the case of conventional air conditioners, there is a problem in which contaminants are not smoothly removed by the filtering means mentioned above, and foreign substances and contamination in the heating and cooling unit, which adjusts the temperature of the air again before the air is introduced into the room. There was a problem that the air temperature could not be smoothly controlled due to the accumulation of substances.

Republic of Korea Patent Publication No. 10-2018-0094158 (2018.08.23.)

The present invention is a technology developed to solve the problems caused by the prior art described above. The conventional air conditioner has a problem of not smoothly removing contaminants by filtering means and adjusts the temperature of the air before it is introduced into the room. As foreign substances and contaminants accumulate in the cooling and heating parts, problems arise that prevent the air temperature from being smoothly controlled.

After sucking in the indoor air of a large-scale building and mixing it with the outdoor air, contaminants can be smoothly removed through a filtering means, that is, the filter part, and the temperature of the air supplied indoors through the cleaning part can be smoothly controlled. The main purpose is to provide an air conditioner equipped with a cleaning function that allows cleaning of the heating and cooling unit.

In order to achieve the above-mentioned object, the present invention is an air conditioner provided inside a casing 100 composed of a main frame 110 and a panel portion 120 to purify indoor air, A first zone (S1) configured on one side of the casing (100) in the front and rear directions and equipped with an intake duct (D1) through which indoor air flows in; and a portion of which receives indoor air from the first zone (S1) to the outside. A second zone (S2) including a heat exchanger (300) that discharges some of the air and mixes it with the incoming air; and a filter section (500) that receives and filters the mixed air from the second zone (S2), A cooling and heating unit 600 configured to cool or heat the air passing through the filter unit 500, a cleaning unit 900 that cleans the cooling and heating unit 600, and a cleaning control unit that controls the cleaning unit 900 ( 10) a third zone (S3) including; and a fourth zone (S4) provided with an air supply duct (D4) that discharges clean air received from the third zone (S3) into the room; and a vibration damping unit 800 installed at the bottom of the casing 100 to attenuate vibrations generated by the operation of internal components of the casing 100. An air conditioner is presented.

In addition, the filter unit 500 of the present invention is installed on one side of the third zone (S3), and has a housing body 510 with one side and the other side open; and is installed on one inner side of the housing body 510. an Andrea filter 520 that receives the mixed air from the second zone (S2) and performs primary filtration; and an Andrea filter 520 installed inside the housing body 510 and located on the other side of the Andrea filter 520. An electrostatic filter 530; and a photocatalytic filter 540 installed inside the housing body 510 so as to be located on the other side of the electrostatic filter 530; and inside the housing body 510 A carbon filter 550 installed to be located on the other side of the photocatalytic filter 540; and a HEPA filter installed inside the housing body 510 to be located on the other side of the carbon filter 550. (560); and a ULPA filter 570 installed inside the housing body 510 and located on the other side of the HEPA filter 560; and a first bag filter 580 installed on the other side of the housing body 510.

In addition, the third zone (S3) of the present invention is installed inside, but is located on the other side of the filter unit 500, and is installed to measure the flow rate of air filtered in the filter unit 500. It is configured to include a sensor 20, and the cleaning control unit 10 transmits a maintenance notification to the operator or the central control room when the flow rate measured from the first flow detection sensor 20 is less than the preset flow rate. It is characterized by

In addition, the cleaning unit 900 of the present invention includes an air compressor 910 installed outside the third zone (S3) and is installed to be ascendable on one side of the cooling and heating unit 600, and the air compressor ( It is characterized by comprising an air injection unit 920 that receives compressed air from 910) and sprays it in the other direction.

In addition, the cleaning unit 900 of the present invention includes a vacuum pump 930 installed outside the third zone S3 and is installed to be ascendable on the other side of the cooling and heating unit 600, and the vacuum pump It is characterized by being configured to include a suction unit 940 that suctions foreign substances accumulated inside the cooling and heating unit 600 through 930.

In addition, the third zone (S3) of the present invention is characterized by including a second bag filter (30) installed at a distance from the other side of the cooling and heating unit (600).

In addition, the third zone (S3) of the present invention is installed inside, and is installed to be located between the cooling and heating unit 600 and the second bag filter 30, so that the air passing through the cooling and heating unit 600 It is configured to include a second flow rate sensor 40 that measures the flow rate, and the cleaning control unit 10 operates the air compressor when the flow rate measured by the second flow rate sensor 40 is less than the preset flow rate. It is characterized by operating (910) and the air injection unit (920) for a preset time.

In addition, the cleaning control unit 10 of the present invention detects the flow rate measured from the second flow rate sensor 40 and the first flow rate after the operation of the air compressor 910 and the air injection unit 920 is terminated. When the difference in flow rate measured from the sensor 20 is less than a preset difference, the vacuum pump 930 and the suction unit 940 are operated.

In addition, the cleaning control unit 10 of the present invention operates when the flow rate measured from the second flow rate sensor 40 is less than the preset flow rate after the operation of the vacuum pump 930 and the suction part 940 is terminated. It is characterized by sending maintenance notifications to the operator or the central control room.

In addition, the third zone (S3) of the present invention is installed inside, and is configured to include a third flow rate detection sensor (50) installed to be located on the other side of the second bag filter (30), and the detergent The fisherman 10 is characterized in that it transmits a maintenance notification to the worker or the central control room when the flow rate measured by the third flow detection sensor 50 is less than the preset flow rate.

The air conditioner equipped with a cleaning function according to the present invention presented as above takes in the indoor air of a large-scale building, mixes it with outdoor air, and filters it through a filter unit. By installing a plurality of filters in the filter unit, foreign substances and This has the effect of allowing contaminants to be filtered smoothly.

In addition, in the present invention, a first flow rate sensor is installed on the other side of the filter unit to measure the flow rate of air passing through the filter unit, so that when the performance of the filter unit deteriorates, the plurality of filters installed in the filter unit are replaced or cleaned. By doing so, it is possible to achieve the effect of minimizing the deterioration of air filtration performance.

In addition, in the present invention, a second flow rate sensor is installed on the other side of the cooling and heating unit to measure the flow rate of air passing through the cooling and heating unit, so that when foreign substances are excessively accumulated in the cooling and heating unit, the cooling and heating unit is cleaned through the cleaning unit. Not only can the temperature of the air supplied into the room be smoothly adjusted, but it can also achieve the effect of allowing the air to pass smoothly through the cooling and heating unit.

1 is a front view of an air conditioner according to a preferred embodiment of the present invention.
Figure 2 is a plan view of an air conditioner according to a preferred embodiment of the present invention.
Figure 3 is an exploded perspective view of a casing according to a preferred embodiment of the present invention.
Figure 4 is a cross-sectional view of a casing according to a preferred embodiment of the present invention.
Figure 5 is a schematic diagram of the second zone according to a preferred embodiment of the present invention.
Figure 6 is a perspective view of a heat exchanger according to a preferred embodiment of the present invention.
Figure 7 is a partially broken perspective view of a heat exchanger according to a preferred embodiment of the present invention.
Figure 8 is a front view of a damper according to a preferred embodiment of the present invention.
Figure 9 is a side view of a damper according to a preferred embodiment of the present invention.
Figure 10 is a diagram showing an example of use of a blade according to a preferred embodiment of the present invention.
Figure 11 is a side schematic view of the third zone according to a preferred embodiment of the present invention.
Figure 12 is a side schematic diagram showing a filter unit according to a preferred embodiment of the present invention.
Figure 13 is a side schematic diagram showing a cooling/heating unit, an air injection unit, and a suction unit according to a preferred embodiment of the present invention.

The present invention relates to an air conditioner equipped with a cleaning function. To be described in more detail, it is configured to suck in indoor air from a large-scale building, mix it with outdoor air, filter and cool it, and then supply it to the room. A plurality of filters are installed in the filter unit 500 of the third zone (S3) to improve the filtration ability of foreign substances and contaminants so that comfortable air can be supplied indoors, and at the same time, a cleaning unit ( It relates to an air conditioner equipped with a cleaning function that minimizes deterioration in the function of the cooling and heating unit 500 by installing 900) so that air supplied to the room can be supplied more comfortably.

The air conditioner equipped with the cleaning function of the present invention as described above is provided inside a casing 100 composed of a main frame 110 and a panel portion 120 to purify indoor air, A first zone (S1) configured on one side of the casing (100) in the front and rear direction and equipped with an intake duct (D1) through which indoor air flows in; and a portion of which receives indoor air from the first zone (S1) to the outside. A second zone (S2) including a heat exchanger (300) that discharges the air and mixes some of it with the incoming air; and a filter section (500) that receives and filters the mixed air from the second zone (S2). , a cooling and heating unit 600 configured to cool or heat the air passing through the filter unit 500, a cleaning unit 900 that cleans the cooling and heating unit 600, and a cleaning control unit that controls the cleaning unit 900. a third zone (S3) including (10); and a fourth zone (S4) provided with an air supply duct (D4) that discharges clean air received from the third zone (S3) into the room; and a vibration damping unit 800 installed at the bottom of the casing 100 to attenuate vibrations generated by the operation of internal components of the casing 100.

In addition, the filter unit 500 of the present invention is installed on one side of the third zone (S3), and has a housing body 510 with one side and the other side open; and is installed on one inner side of the housing body 510. an Andrea filter 520 that receives the mixed air from the second zone (S2) and performs primary filtration; and an Andrea filter 520 installed inside the housing body 510 and located on the other side of the Andrea filter 520. An electrostatic filter 530; and a photocatalytic filter 540 installed inside the housing body 510 so as to be located on the other side of the electrostatic filter 530; and inside the housing body 510 A carbon filter 550 installed to be located on the other side of the photocatalytic filter 540; and a HEPA filter installed inside the housing body 510 to be located on the other side of the carbon filter 550. (560); and a ULPA filter 570 installed inside the housing body 510 and located on the other side of the HEPA filter 560; and a first bag filter 580 installed on the other side of the housing body 510.

In addition, the third zone (S3) of the present invention is installed inside, but is located on the other side of the filter unit 500, and is installed to measure the flow rate of air filtered in the filter unit 500. It is configured to include a sensor 20, and the cleaning control unit 10 transmits a maintenance notification to the operator or the central control room when the flow rate measured from the first flow detection sensor 20 is less than the preset flow rate. It is characterized by

In addition, the cleaning unit 900 of the present invention includes an air compressor 910 installed outside the third zone (S3) and is installed to be ascendable on one side of the cooling and heating unit 600, and the air compressor ( It is characterized by comprising an air injection unit 920 that receives compressed air from 910) and sprays it in the other direction.

In addition, the cleaning unit 900 of the present invention includes a vacuum pump 930 installed outside the third zone S3 and is installed to be ascendable on the other side of the cooling and heating unit 600, and the vacuum pump It is characterized by being configured to include a suction unit 940 that suctions foreign substances accumulated inside the cooling and heating unit 600 through 930.

In addition, the third zone (S3) of the present invention is characterized by including a second bag filter (30) installed at a distance from the other side of the cooling and heating unit (600).

In addition, the third zone (S3) of the present invention is installed inside, and is installed to be located between the cooling and heating unit 600 and the second bag filter 30, so that the air passing through the cooling and heating unit 600 It is configured to include a second flow rate sensor 40 that measures the flow rate, and the cleaning control unit 10 operates the air compressor when the flow rate measured by the second flow rate sensor 40 is less than the preset flow rate. It is characterized by operating (910) and the air injection unit (920) for a preset time.

In addition, the cleaning control unit 10 of the present invention detects the flow rate measured from the second flow rate sensor 40 and the first flow rate after the operation of the air compressor 910 and the air injection unit 920 is terminated. When the difference in flow rate measured from the sensor 20 is less than a preset difference, the vacuum pump 930 and the suction unit 940 are operated.

In addition, the cleaning control unit 10 of the present invention operates when the flow rate measured from the second flow rate sensor 40 is less than the preset flow rate after the operation of the vacuum pump 930 and the suction part 940 is terminated. It is characterized by sending maintenance notifications to the operator or the central control room.

In addition, the third zone (S3) of the present invention is installed inside, and is configured to include a third flow rate detection sensor (50) installed to be located on the other side of the second bag filter (30), and the detergent The fisherman 10 is characterized in that it transmits a maintenance notification to the worker or the central control room when the flow rate measured by the third flow detection sensor 50 is less than the preset flow rate.

Hereinafter, the present invention will be described in detail with reference to Figures 1 to 13 showing embodiments of the present invention.

As shown in FIG. 3, the casing 100 is intended to protect the main components of the air conditioner according to the present invention, and includes a plurality of main frames 110 (profiles) and a plurality of panel parts 120. Each section is formed in the shape of a plurality of enclosures, and each section is connected to each other and arranged in the front and back directions to form the casing 100.

That is, the casing 100 is formed by sequentially arranging and connecting the first zone (S1), the second zone (S2), the third zone (S3), and the fourth zone (S4) in the front-back direction. At this time, one The adjacent areas of the pair are made in an open state on the facing side, and are connected by a connecting member 130 made of a canvas material so as to be in a communication state.

Meanwhile, as shown in Figures 3 and 4, the casing 100 is made of neoprene rubber, a synthetic rubber having properties such as elasticity, water resistance, oil resistance, chemical resistance, abrasion resistance, and heat resistance, and is formed on one side of the main frame 110. It further includes a packing portion 140 that is adhesively provided, and the main frame 110 is arranged and fastened horizontally, vertically, and height to form the framework of the rectangular casing 100.

At this time, the plurality of main frames 110 that are orthogonally connected are fastened by corner mounts 150 formed by injection molding of a reinforced plastic material, thereby improving the structural strength of the connection between the main frames 110. .

The panel portion 120 includes a pair of plates arranged face-to-face and spaced apart, a border member connecting the space between the pair of plates, and hard urethane filled in the internal space formed by the plate and the border member. do.

Accordingly, the panel part 120 has thermal insulation, heat insulation and sound insulation effects, and is inserted into the space partitioned by the main frame 110. At this time, it is in surface contact with the packing part 140. It is provided and fastened to the main frame 110 by bolts, screws, etc., and the joint gap between the components is caulked with a joint material such as silicone.

Meanwhile, in the first area (S1), an inflow blower (200) is provided to introduce indoor air, and the outlet of the inflow blower (200) is directed toward the second area (S2). It is provided in the zone (S1), and the outlet of the inlet blower 200 and the inlet of the second zone (S2) are connected by a connecting member 130 made of canvas, so that the inflow air is connected to the second zone (S2). Ensure smooth movement to area (S2).

Meanwhile, according to FIG. 5, the second zone (S2) is a heat exchanger 300 in order to move to the next process after heat exchange occurs in the process of discharging the sucked indoor air to the outside or sucking and mixing the outside air. It is composed including.

As shown in FIGS. 6 and 7, the heat exchange unit 300 is configured by stacking a plurality of heat exchange plates 310 and forming a flow path between a pair of adjacent heat exchange plates 310. The plate 310 is constructed by coating the surface of a thin aluminum plate with epoxy.

To elaborate, the heat exchange plate 310 is a first heat plate 311 and a second heat plate disposed spaced apart from the first heat plate 311 in a face-to-face state, with both ends bent and joined to the first heat plate 311. It includes 312, and the joint portion 313 of the first heat plate 311 and the second heat plate 312 is folded inward a plurality of times.

At this time, the first heat plate 311 is configured with a heat conductive portion 314 convexly recessed toward the second heat plate 312, and the joint portion 313 of the first heat plate 311 and the second heat plate 312. In order to prevent the incoming air from being contaminated, it is folded multiple times to maintain airtightness.

In addition, the heat conductive portion 314 has the end of the convex portion in surface contact with the first heat plate 312 to prevent air passing between the first heat plate 311 and the second heat plate 312. Improve heat conduction efficiency.

A plurality of heat exchange plates 310 configured as above are stacked facing each other, and the joint portions 313 of the first heat plate 311 and the second heat plate 312 are stacked so that they cross each other alternately, and the first heat exchange plates 310 are isolated from each other. The flow path 315 and the second flow path 316 are formed and locked together by the main frame 110 to form the heat exchange unit 300.

The heat exchange unit 300 is formed in a form where the corners of the main frame 110 are chamfered, and the corners of the heat exchange unit 300 are provided in contact with the upper, lower, front and rear surfaces in the second zone (S2). As a result, the internal space of the second zone (S2) is divided into four by the heat exchange unit 300, and a pair of spaces diagonally facing each other with respect to the heat exchange unit 300 are in a state of communication with each other. .

In detail, the internal space of the second zone (S2) is an inlet zone (R1), which is an upper area adjacent to the first zone (S1), with respect to the heat exchange unit 300, and an upper end adjacent to the third zone (S3). It includes a discharge zone (R2) as a side zone, a delivery zone (R3) as a bottom zone adjacent to the first zone (S1), and a mixing zone (R4) as a bottom zone adjacent to the third zone (S3).

The inflow area (R1) is formed in communication with the ventilation duct (D2) to bring in outside air and deliver the outside air to the first flow path 315 of the heat exchange unit 300, and the ventilation duct (D2) has a first A damper 400a is provided to control opening and closing.

The discharge area (R2) is formed in communication with an exhaust duct (D3) that receives indoor air from the second flow path 316 of the heat exchange unit 300 and discharges it to the outside, and the exhaust duct (D3) has a second damper. (400b) is provided to control opening and closing.

The delivery zone (R3) is in communication with the inlet of the second zone (S2) and receives the sucked indoor air and delivers the sucked indoor air to the second flow passage 316, or delivers indoor air to the mixing zone (R4). and a third damper (400c) is provided between the transmission zone (R3) and the mixing zone (R4) to control opening and closing.

The mixing zone (R4) mixes the indoor air delivered from the delivery zone (R3) with the outside air delivered from the inlet zone (R1) and delivers it to the filter unit 500.

The indoor air sucked in by the heat exchange unit 300 configured as described above can be discharged to the outside or supplied back into the room after being filtered by adjusting the opening and closing of each damper 400 as needed. .

Meanwhile, as shown in Figures 8 and 9, the first damper 400a, the second damper 400b, and the third damper 400c (hereinafter referred to as 'damper 400') have the installed configuration. It is configured to adjust the aperture ratio, and more specifically, it includes a damper frame 410, a blade 420, an interlocking link 430, and an actuator 440.

The damper frame 410 is made of an aluminum profile, and the longitudinal and transverse members are arranged and fastened to form a square frame.

A plurality of blades 420 are arranged in the vertical direction inside the damper frame 410.

To elaborate, the blades 420 are arranged in the vertical direction in the inner space of the damper frame 410 in a state in which the central axis is hinged by a longitudinal member and a bearing of the damper frame 410.

At this time, a pair of blades 420 adjacent to each other in the vertical direction are composed of opposing wing dampers 400 provided to rotate in opposite directions, and when the blades 420 are rotated to the maximum in the forward direction, the blades 420 The ends of (420) are in contact with the facing surfaces of blades 420 arranged adjacently to seal the internal space of the damper frame 410, and the blades 420 are rotated to the maximum in the reverse direction. At this time, the internal space of the damper frame 410 is opened to the greatest extent.

In addition, a pair of blades 420 adjacent in the vertical direction are connected to the stopper 450 to allow the blades 420 to rotate in a limited manner.

Meanwhile, the interlocking link 430 is configured to allow a plurality of blades 420 to operate interlocked and is provided inside the longitudinal member of the damper frame 410.

The actuator 440 is used to operate the interlocking link 430, and the actuator 440 moves the interlocking link 430 in the vertical direction.

According to the above configuration, when the actuator 440 is operated and the interlocking link 430 is moved upward, each duct equipped with the damper 400 is in a sealed state, and the interlocking link 430 is moved downward. When moved, each duct provided with the damper 400 is in an open state.

To elaborate, when the interlocking link 430 moves upward, the blade 420 rotates and the ends of a pair of blades 420 adjacent in the vertical direction come into surface contact with each other, and thus the duct It becomes closed.

At this time, as shown in FIG. 10, in order to improve airtightness between the blades 420, a first step 421 and a second step are formed at the vertical ends of the blade 420, respectively, and the A sealing packing 423 is provided in the first step portion 421 and the second step portion 421.

To elaborate, a first wing tip 421a and a second wing tip 422a are formed extending from the vertical ends of the blade 420 by the first step portion 421 and the second step portion 422, , the pair of blades 420 is provided such that the first step portion 421 and the second step portion 422 face each other, and the first wing tip 421a and the second wing tip 422a overlap each other. do.

At this time, the sealing packing 423 is made of a packing with hydraulic or pneumatic pressure formed therein, and is provided on the inner surface facing the second wing tip 422a and the first wing tip 421a.

According to the above configuration, when the pair of blades 420 are fully rotated in the forward direction, the pair of sealing packings 423 press each other to maintain airtightness between the blades 420.

According to the above configuration, in the present invention, the opening rate of each damper 400 can be adjusted by controlling the operation of the blade 420, and the amount of wind flowing into the duct where each damper 400 is installed is adjusted in proportion to this. .

Meanwhile, as shown in FIG. 5, the second zone S2 is installed on the other side of the damper 400 to increase the temperature of the air passing through the damper 400 to increase the flow rate of air, thereby increasing the movement of air. It is configured to include an electric heater 60 that allows this to occur smoothly.

To elaborate, the electric heater 60 increases the temperature of the air that has passed through the damper 400, thereby minimizing the accumulation of particulate fluid contained in the air at the bottom of the mixing zone (R4). This achieves the effect of reducing maintenance demands in area (R4).

At this time, the electric heater 60 prevents the temperature of the air passing through the damper 400 from rising to a temperature higher than 30 degrees, which allows the air temperature to be smoothly controlled in the cooling and heating unit 600, which will be explained in detail later. This is to ensure that it can be done.

Meanwhile, the third zone (S3) is for filtering the heat-exchanged air and cooling or heating it to a certain temperature, and includes a filter unit 500, a cooling/heating unit 600, a cleaning unit 900, and a cleaning control unit 10. ) includes.

The filter unit 500 is used to remove fine dust and oil components contained in the air, as well as bad odors, and is made up of a plurality of multiple filters.

Specifically, the filter unit 500 is installed on one side of the third zone (S3), has a housing body 510 with one side and the other side open, and is installed on one inner side of the housing body 510 to An Andrea filter 520 that receives mixed air from zone 2 (S2) and performs primary filtration, and an electrostatic filter installed inside the housing body 510 and located on the other side of the Andrea filter 520. A filter 530, a photocatalytic filter 540 installed inside the housing body 510 and located on the other side of the electrostatic filter 530, and a photocatalytic filter 540 installed inside the housing body 510, , a carbon filter 550 installed to be located on the other side of the photocatalytic filter 540, and a HEPA filter 560 installed inside the housing body 510 to be located on the other side of the carbon filter 550. ), a Wolfa filter 570 installed inside the housing body 510 and located on the other side of the HEPA filter 560, and a first bag filter installed on the other side of the housing body 510 ( 580).

The housing body 510 is installed on one side of the third zone (S3), and a plurality of filters are installed inside, so that the air moved through the second zone (S2) is filtered and then sent to the fourth zone (S4). It can be moved, and for this purpose, the upper and lower parts are installed in close contact with the upper and lower parts of the third area (S3), and one side and the other side are open.

The Andrea filter 520 ensures that the air moved through the second zone (S2) is filtered first, and relatively heavy liquid particulates are filtered through inertial separation, and the particulate matter contained in the air is filtered. Filter the liquid. The Andrea filter 520 can be replaced during maintenance to maintain filtration performance.

The electrostatic filter 530 filters the air filtered through the Andrea filter 520 and removes cigarette smoke, bacteria, mold, pollen, etc. from the air through a separation method using static electricity. Remove contained foreign substances and contaminants. During maintenance, the electrostatic filter 530 can be separated from the housing body 510, washed, dried, and reinstalled to maintain filtration performance.

The photocatalytic filter 540 allows the air filtered through the electrostatic filter 530 to be filtered, is made of titanium dioxide, and blocks oil and water particles. As is generally known in the art, air purification, It filters contaminants contained in the air with functions such as deodorization, anti-fouling, water purification, and antibacterial function. During maintenance, the photocatalytic filter 540 can be separated from the housing body 510, cleaned with chemicals, removed from grease, etc., dried, and reinstalled to maintain filtration performance.

The carbon filter 550 filters the air filtered through the photocatalytic filter 540, removes odors generated in daily life such as food odors and cigarette odors through adsorption, and filters various odors. . This carbon filter 550 can maintain filtration performance by being replaced at regular intervals, and can maintain filtration performance by being replaced during maintenance.

The HEPA filter 560 filters the air filtered through the carbon filter 550 and removes fine particles, and any commonly known HEPA filter may be used. This HEPA filter 560 can be replaced during maintenance to maintain filtration performance.

The Ulpa filter 570 filters the air filtered through the HEPA filter 560 and removes fine particles, but also removes smaller fine particles that are not filtered by the HEPA filter 560. Any commonly known ULPA filter can be used, and the air that has passed through the HEPA filter 560 is filtered to make the air more comfortable. Like the HEPA filter 560, this ULPA filter 570 can be replaced during maintenance to maintain filtration performance.

The first bag filter 580 filters the air filtered through the ULPA filter 570, and ultimately allows foreign substances and contaminants contained in the air to be collected and removed, which is generally known in the related art. Any bag filter can be used. This first bag filter 580 can be replaced by a maintenance machine to maintain filtration performance.

The filter unit 500 of the present invention, which is composed of a plurality of filters as described above, can easily remove foreign substances and contaminants in the oil and moisture state contained in the mixed air mixed with external air, so that more comfortable air can be filtered and supplied indoors. Realize the desired effect.

That is, in the filter unit 500, air from which oil and moisture are first removed through the Andrea filter 520 passes through the electrostatic filter 530 to first remove harmful substances, and oil and moisture are first removed through the photocatalytic filter 540. The secondly removed air is thirdly removed through the carbon filter (550) to absorb and remove oil and moisture and harmful substances, and finally fine dust is removed through the HEPA filter (560), the Ulpa filter (570), and the first bag filter (580). This ensures that comfortable air can be supplied indoors.

In addition, the filter unit 500 maintains the cooling and heating unit 600 by minimizing the accumulation of dust and contamination by contaminants in the cooling and heating unit 600, which will be described in detail later, through the purification ability described above. By minimizing , the effect of maintaining the performance of the cooling and heating unit 600 for a long period of time is realized.

In connection with the above, the cooling and heating unit 600 is provided in the flow direction of the filter unit 500 to cool or heat the air passing through the filter unit 500 to a set temperature.

To elaborate, the cooling and heating unit 600 is for cooling or heating the delivered air and is formed of a copper pipe or an aluminum pipe, so that water provided from the outside flows in a heated or cooled state within the pipe, and the delivered mixed air is In the process of passing through the cooling/heating unit 600, heat is exchanged and the temperature can be adjusted to a set level.

At this time, a drain plate 610 is further provided at the lower part of the cooling and heating unit 600 to collect and discharge moisture naturally occurring in the cooling and heating unit 600.

In addition, the third zone (S3) is installed inside, but located on the other side of the filter unit (500), and measures the flow rate of air filtered in the filter unit (500) to the cleaning control unit (10). It is configured to include a first flow rate sensor 20 that transmits the measured air flow rate information.

The cleaning control unit 10 transmits a maintenance notification to the operator or the central control room when the flow rate measured from the first flow detection sensor 20 is less than the preset flow rate, and the operator or the central control room accordingly sends the maintenance notification. When this is received, if the flow rate measured from the first flow detection sensor 20 is less than the preset flow rate, it is determined that the performance of the filter unit 500 has deteriorated so that the performance of the filter unit 500 can be restored. Carry out maintenance.

At this time, it will be apparent that the cleaning control unit 10 is equipped with a wired or wireless communication unit to enable communication with an operator or a central control room.

In addition, the cleaning control unit 10 controls the operation of the cleaning unit 900, and when cleaning of the cooling and heating unit 600 is required, the cleaning unit 900 is operated to clean the cooling and heating unit 600. By cleaning, the performance of the cooling and heating unit 600 can be maintained.

At this time, the cleaning unit 900 is installed to be able to be raised and lowered on one side of the air compressor 910 and the cooling and heating unit 600 installed outside the third zone (S3), and is operated by the air compressor 910. It is configured to include an air injection unit 920 that receives compressed air and sprays the compressed air in the other direction.

The cleaning unit 900 controls the operation of the air compressor 910 and the lifting operation of the air injection unit 920 under the control of the cleaning control unit 10, thereby compressing the air conditioning unit 600 on one side. By spraying air to remove foreign substances in the other direction, a cleaning effect is achieved.

In addition, the air injection unit 920 includes a pair of rails (not shown) installed on one front and one rear edge of the cooling and heating unit 600, and is installed to be able to be raised and lowered along the rails, It is connected to the air compressor 910 and includes an air injection nozzle (not shown) that receives compressed air and sprays it in the other direction. At this time, it will be apparent that the air injection unit 920 may be provided with a cylinder or a servo motor that raises and lowers the air injection nozzle.

In addition, the cleaning unit 900 of the present invention is installed to be able to be raised and lowered on the other side of the vacuum pump 930 and the cooling and heating unit 600 installed outside the third zone (S3), and the vacuum pump ( It is configured to include a suction unit 940 that suctions foreign substances accumulated inside the cooling and heating unit 600 through 930.

The cleaning unit 900 controls the operation of the vacuum pump 930 and the lifting and lowering operation of the suction unit 940 under the control of the cleaning control unit 10, thereby providing the cooling and heating on the other side of the cooling and heating unit 600. By suctioning and removing foreign substances accumulated on the inside of the unit 600, a cleaning effect is realized.

In additional explanation, the suction unit 940 is installed to be able to be raised and lowered along a pair of rails (not shown) installed on the front and rear edges of the other side of the cooling and heating unit 600, and the It is connected to the vacuum pump 930 and includes a suction injection nozzle (not shown) that sucks air from the other side of the cooling and heating unit 600. At this time, it will be apparent that the suction unit 940 may be provided with a cylinder or a servo motor that raises and lowers the suction injection nozzle.

The air injection nozzle and suction injection nozzle as described above are normally located at the upper or lower part of the cooling/heating unit 600 and are controlled by the cleaning control unit 10 to be raised and lowered.

In addition, the third zone (S3) includes a second bag filter 30 installed to be spaced apart from the other side of the cooling and heating unit 600. The second bag filter 30 is installed on the other side of the cooling and heating unit 600. ) not only allows the air that has passed through to be finally filtered once more, but also minimizes the movement of foreign substances to the fourth zone (S4) when cleaning the cooling and heating unit (600) through the air injection unit (920). It achieves the effect of preventing pollution in zone 4 (S4).

At this time, the second bag filter 30, like the first bag filter 580 described above, may be any conventionally known bag filter. This second bag filter 30 can be replaced by a maintenance machine to maintain filtration performance.

In connection with the above, the third zone (S3) is installed inside, and is installed to be located between the cooling and heating unit 600 and the second bag filter 30, and is installed so that it passes through the cooling and heating unit 600. It is configured to include a second flow rate sensor 40 that measures the air flow rate and transmits the measured air flow rate information to the cleaning control unit 10.

At this time, the cleaning control unit 10 operates the air compressor 910 and the air injection unit 920 for a preset time when the flow rate measured by the second flow rate sensor 40 is less than the preset flow rate.

That is, the cleaning control unit 10 operates when the flow rate measured by the second flow rate sensor 40 is less than the preset flow rate and the air that has passed through the filter unit 500 passes through the cooling and heating unit 600. If it is determined that excessive foreign matter is accumulated inside the cooling and heating unit 600 and air is not flowing smoothly, the air compressor 910 and air injection unit 920 of the cleaning unit 900 are operated for a preset time. , so that the performance of the cooling and heating unit 600 can be restored.

In addition, the cleaning control unit 10 controls the flow rate measured from the second flow rate detection sensor 40 and the first flow rate detection sensor 20 after the operation of the air compressor 910 and the air injection unit 920 is terminated. ), the vacuum pump 930 and the suction unit 940 are operated when the difference in flow rate measured is less than a preset difference amount.

In addition, the operation of the vacuum pump 930 and the suction unit 940 of the cleaning unit 900 is the operation of the air compressor 910 and the air injection unit 920 of the cleaning unit 900 described above. Unlike the second flow detection sensor 40, it is not operated only with the flow rate measured from the second flow detection sensor 40, and after operation of the air compressor 910 and the air injection unit 920 of the cleaning unit 900, the second flow detection sensor is operated. After checking the difference between the flow rate measured from (40) and the flow rate measured from the first flow rate detection sensor (20), it is operated if the difference is less than a preset amount.

The reason why the vacuum pump 930 and the suction unit 940 are not operated using only the flow rate measured from the second flow detection sensor 40 is that the cleaning operation through the air compressor 910 and the air injection unit 920 is performed. This is because sufficient cleaning effect can be obtained.

In addition, the operation of the vacuum pump 930 and the suction unit 940 causes foreign substances to remain on the other side of the cooling and heating unit 600, which has a complicated interior, even after continuous cleaning through the air compressor 910 and the air injection unit 920. Accumulation can have a significant impact on the flow rate of air, so it is determined more precisely than judging only the flow rate measured from the second flow rate detection sensor 40 after operation of the air compressor 910 and the air injection unit 920. By making this possible through the difference between the flow rate measured from the second flow rate detection sensor 40 and the flow rate measured from the first flow rate detection sensor 20, the performance through cleaning of the cooling and heating unit 600 is improved. Ensure smooth restoration.

To further explain, the flow rate measured from the second flow rate sensor 40 and the first flow rate sensor 20 are greater than the range in which the flow rate measured from the second flow rate sensor 40 is less than the preset flow rate. Since the range in which the difference between the measured flow rates is less than the preset difference can more accurately confirm the flow rate of air moving from the second area (S2), the above and The same effect can be achieved.

In addition, the cleaning control unit 10 operates when the flow rate measured from the second flow detection sensor 40 is lower than the preset flow rate after the operation of the vacuum pump 930 and the suction part 940 is terminated. Send maintenance notification to the control room.

That is, the cleaning control unit 10 performs cleaning of the cooling and heating unit 600 by checking the air flow rate through the second flow rate detection sensor 40 even after cleaning the cooling and heating unit 600 through the cleaning unit 900. You can check whether it has been done efficiently, allowing you to accurately determine maintenance needs.

In connection with the above, the third zone (S3) is installed inside, but located on the other side of the second bag filter (30), and measures the flow rate of air passing through the cooling and heating unit (600) to determine the amount of detergent. It is configured to include a third flow rate detection sensor 50 that transmits the measured air flow rate information to the fisherman 10.

In addition, the cleaning control unit 10 transmits a maintenance notification to the operator or the central control room when the flow rate measured from the third flow detection sensor 50 is less than the preset flow rate, and accordingly, the operator or the central control room performs the maintenance. When a maintenance notification is received, if the flow rate measured from the third flow detection sensor 50 is less than the preset flow rate, it is determined that the performance of the second bag filter 30 has deteriorated, and the performance of the second bag filter 30 is determined to be reduced. Perform maintenance to restore performance.

Meanwhile, in the fourth zone (S4), an air supply blower is provided on the downstream side of the cooling and heating unit (600) in the third zone (S3) and receives air cooled and heated by the cooling and heating unit (600) and supplies it to the room. (700) is provided.

The air supply blower 700 allows air to be smoothly moved through the second zone (S2) and the third zone (S3) and supplied indoors.

Meanwhile, the vibration damping unit 800 is provided at the lower part of the casing 100 to attenuate vibration generated by the operation of the driver that supplies power to the inflow blower 200 and the air supply blower 700. As such, any conventionally used material may be used, so detailed description will be omitted.

The above has been described with reference to preferred embodiments of the present invention, and the present invention is not limited to the above embodiments, and through the above embodiments, those skilled in the art will understand the gist of the present invention. It can be implemented with various changes without departing from the scope.

D1: Inlet duct D2: Ventilation duct
D3: Exhaust duct D4: Air supply duct
S1: Zone 1 S2: Zone 2
S3: Area 3 S4: Area 4
R1: Inlet area R2: Discharge area
R3: Delivery zone R4: Mixing zone
10: Cleaning control unit 20: First flow detection sensor
30: Second bag filter 40: Second flow detection sensor
50: Third flow detection sensor 60: Electric heater
100: Casing 110: Main frame
120: panel part 130: connection member
140: Packing part 150: Corner mount
200: blower for inflow
300: heat exchange unit 310: heat exchange plate
311: first heat plate 312: second heat plate
313: junction 314: heat conduction part
315: 1st Euro 316: 2nd Euro
400: Damper 400a: First damper
400b: 2nd damper 400c: 3rd damper
410: Frame for damper 420: Blade
421: 1st step portion 421a: 1st wing tip
422: 2nd stage 422a: 2nd wing tip
423: Sealing packing 430: Interlocking link
440: Actuator 450: Stopper
500: Filter unit 510: Housing body
520: Andrea Filter 530: Electrostatic Filter
540: Photocatalyst filter 550: Carbon filter
560: HEPA filter 570: Ulpa filter
580: 1st bag filter
600: Cooling and heating unit 610: Drain plate
700: Air supply blower
800: Vibration damping unit
900: Cleaning unit 910: Air compressor
920: Air injection unit 930: Vacuum pump
940: suction part

Claims (10)

In an air conditioner provided inside a casing 100 composed of a main frame 110 and a panel portion 120 to purify indoor air,
A first zone (S1) formed on one side of the casing (100) in the front and rear direction and provided with an intake duct (D1) through which indoor air flows; and
A second zone (S2) including a heat exchanger (300) that receives indoor air from the first zone (S1), discharges some of it to the outside, and mixes some of it with the incoming air; and
A filter unit 500 that receives and filters the mixed air in the second zone (S2), a cooling and heating unit 600 configured to cool or heat the air passing through the filter unit 500, and the cooling and heating unit ( A third zone (S3) including a cleaning unit 900 for cleaning the 600 and a cleaning control unit 10 for controlling the cleaning unit 900;
A fourth zone (S4) equipped with an air supply duct (D4) that discharges clean air received from the third zone (S3) into the room; and
A vibration damping unit 800 installed at the bottom of the casing 100 to attenuate vibration generated by the operation of internal components of the casing 100,
The filter unit 500 is
A housing body 510 installed on one side of the third zone (S3) and open on one side and the other side; and
An Andrea filter 520 installed on one side of the interior of the housing main body 510 to receive mixed air from the second zone (S2) and perform primary filtration;
An electrostatic filter 530 installed inside the housing body 510 and located on the other side of the Andrea filter 520; and
A photocatalyst filter 540 installed inside the housing body 510 and located on the other side of the electrostatic filter 530;
A carbon filter 550 installed inside the housing body 510 and located on the other side of the photocatalytic filter 540; and
A HEPA filter 560 installed inside the housing body 510 and located on the other side of the carbon filter 550;
A ULPA filter 570 installed inside the housing body 510 and located on the other side of the HEPA filter 560; and
An air conditioner with a cleaning function, comprising a first bag filter (580) installed on the other side of the housing body (510).
delete According to paragraph 1,
The third area (S3) is
A first flow rate sensor 20 is installed inside and located on the other side of the filter unit 500 to measure the flow rate of air filtered by the filter unit 500,
The cleaning control unit 10 is
An air conditioner with a cleaning function, characterized in that when the flow rate measured from the first flow detection sensor (20) is less than the preset flow rate, a maintenance notification is sent to the operator or the central control room.
According to paragraph 3,
The washing unit 900 is
An air compressor 910 installed outside the third zone (S3); and
A cleaning function comprising an air injection unit 920 that is installed on one side of the cooling and heating unit 600 to be able to be raised and lowered, and receives compressed air from the air compressor 910 and sprays it in the other direction. An air conditioner equipped with this.
According to paragraph 4,
The washing unit 900 is
A vacuum pump 930 installed outside the third zone (S3); and
A suction unit 940 is installed on the other side of the cooling and heating unit 600 to be able to be raised and lowered, and suctions foreign substances accumulated inside the cooling and heating unit 600 through the vacuum pump 930. An air conditioner equipped with a characteristic cleaning function.
According to clause 5,
The third area (S3) is
An air conditioner with a cleaning function, characterized in that it includes a second bag filter (30) installed to be spaced apart from the other side of the cooling and heating unit (600).
According to clause 6,
The third area (S3) is
A second flow rate sensor 40 is installed inside and located between the cooling and heating unit 600 and the second bag filter 30 to measure the flow rate of air passing through the cooling and heating unit 600. It consists of ;,
The cleaning control unit 10 is
Air with a cleaning function, characterized in that the air compressor 910 and the air injection unit 920 are operated for a preset time when the flow rate measured from the second flow rate sensor 40 is less than the preset flow rate. Harmonizer.
In clause 7,
The cleaning control unit 10 is
After the operation of the air compressor 910 and the air injection unit 920 is terminated, the difference between the flow rate measured by the second flow rate sensor 40 and the flow rate measured by the first flow rate sensor 20 is measured. An air conditioner with a cleaning function, characterized in that the vacuum pump (930) and the suction unit (940) are operated when the difference is less than the set difference.
According to clause 8,
The cleaning control unit 10 is
After the operation of the vacuum pump 930 and the suction unit 940 is terminated, if the flow rate measured from the second flow detection sensor 40 is less than the preset flow rate, a maintenance notification is sent to the operator or the central control room. An air conditioner equipped with a characteristic cleaning function.
According to clause 9,
The third area (S3) is
It is installed inside, but is configured to include a third flow detection sensor 50, which is installed so as to be located on the other side of the second bag filter 30,
The cleaning control unit 10 is
An air conditioner with a cleaning function, characterized in that when the flow rate measured from the third flow rate detection sensor (50) is less than the preset flow rate, a maintenance notification is sent to the operator or the central control room.