KR20220152024A - Eliminator and outdoor air handling unit having the same - Google Patents

Abstract

The present invention relates to an eliminator having a structure capable of reducing the rate of scattering water to the rear side or downstream of the eliminator based on the flow direction of air, and an outdoor air handling unit having the same. According to the present invention, the eliminator comprises a first filter medium and a second filter medium having a wavy shape for receiving moisture and absorbing a substance to be absorbed from the air. The first filter medium and the second filter medium are provided in plurality and are alternately arranged with each other along a direction crossing the flow direction of air, wherein the length of the first filter medium and the length of the second filter medium are formed to be different from each other in the flow direction of the air.

Description

Eliminator and outdoor air conditioner having the same {ELIMINATOR AND OUTDOOR AIR HANDLING UNIT HAVING THE SAME}

The present invention is installed inside the air conditioning system of a building to remove water-soluble gaseous contaminants (Chemical Contaminants) contained in the outside air, and at the same time, a water showering system that simultaneously humidifies and is provided in the water showering system It's about the eliminator that becomes.

In general, high-precision electronic products such as semiconductors and displays are manufactured in clean rooms in which air temperature, humidity, and indoor pressure are precisely controlled. An outdoor air conditioner is installed to remove contaminants such as dust included in the outdoor air flowing into the clean room and to control the temperature and humidity.

The external air conditioner is provided with a water showering system for removing water-soluble chemical contaminants from the air and simultaneously humidifying the air. The water showering system refers to a system that sprays water into an eliminator to remove water-soluble gaseous contaminants contained in air passing through the eliminator by a gas/liquid contact principle.

Republic of Korea Utility Model Registration No. 20-0452883 (2011.03.17.) discloses a water object gradient exchange type eliminator. The eliminator disclosed in the above Registered Utility Model Publication is formed by stacking a plurality of locking plates having a plurality of corrugated cross-sections alternately inclined at a predetermined angle. When water is sprayed from the liquid injection nozzle to the eliminator, water-soluble gaseous contaminants and dust flowing in a straight line along the air flow path do not pass through and collide with each air flow path in an oblique direction so that they are filtered and easily dropped while flowing at an angle. By doing so, water-soluble gaseous contaminants and dust can be removed.

However, in the eliminator, a phenomenon in which water is scattered to the rear side (or downstream) along the air flow direction may occur. In addition, since the outdoor air conditioner includes a fan on the downstream side of the eliminator based on the flow of air, there is a possibility of failure of the fan when water is scattered.

In addition, the differential pressure between the upstream and downstream sides of the eliminator affects the energy consumption of the fan, but the utility model registration does not disclose a solution for improving this.

A first object of the present invention is to provide an eliminator having a structure capable of reducing the rate at which water is scattered to the rear side or downstream of the eliminator based on the flow direction of air.

In addition, the second object of the present invention is to maintain a ratio of water scattered to the front part of the eliminator higher than the ratio of water scattered to the rear part, to provide a structure capable of improving the drying phenomenon occurring on the front part of the eliminator. It is to present an eliminator.

A third object of the present invention is to provide an eliminator having a structure capable of reducing a differential pressure between an upstream side and a downstream side based on the eliminator.

In order to achieve the above object of the present invention, the present invention includes a first filter medium and a second filter medium having a wavy shape for receiving moisture and allowing the target material to be absorbed to be absorbed in moisture so as to remove the target material from the air. And, the first filter medium and the second filter medium are provided in plurality and are alternately arranged with each other along a direction crossing the air flow direction, and the length of the first filter medium and the second filter medium in the air flow direction The length of discloses an eliminator formed differently from each other and an external air conditioner having the same.

Peaks and valleys forming the wavy shape are alternately and repeatedly formed in the first filter material and the second filter material, and the peaks or valleys formed in the first filter material are upward from the front end to the rear end of the first filter material. and extends in an oblique direction toward the air flow direction, the length of the first filter medium may be longer than that of the second filter medium in the air flow direction.

In the air flow direction, the front end of the first filter medium and the front end of the second filter medium are formed at the same position, and in the air flow direction, the rear end of the first filter medium faces the rear of the eliminator. It may protrude more than the rear end of the filter medium.

A length from the front end to the rear end of the second filter medium in the air flow direction may be 75 to 98% of a length from the front end to the rear end of the first filter medium.

A length from the front end to the rear end of the second filter medium in the flow direction of the air may be 8 mm or more shorter than a length from the front end to the rear end of the first filter medium.

The length from the front end to the rear end of the first filter material in the air flow direction may be 50 mm to 400 mm, and when the length from the front end to the rear end of the first filter material is 50 mm or more and 200 mm or less, from the front end of the second filter material The length to the rear end may be 75 to 95% of the length from the front end to the rear end of the first filter material, and when the length from the front end to the rear end of the first filter material is greater than 200 mm and less than or equal to 400 mm, from the front end of the second filter material The length to the rear end may be 90 to 98% of the length from the front end to the rear end of the first filter medium.

An angle between the flow direction of the air and the extension direction of the peaks or valleys forming the wavy shape is defined as a valley angle, and the peaks or valleys formed in the first filter medium or the second filter medium are When the second filter material extends in a direction inclined upward from the front end to the rear end, the bone angle is defined as a positive bone angle, and a peak or valley formed in the first filter material or the second filter material is the first filter material. When the filter material or the second filter material extends in an oblique direction from the front end to the rear end, the bone angle is defined as a negative bone angle, and the first filter material and the second filter material have different bone angles. The absolute value of the bone angle of the second filter material may be smaller than the absolute value of the bone angle of the first filter material.

The first filter material may be formed to have a positive bone angle, and the second filter material may be formed to have a bone angle corresponding to +70% to -70% of the bone angle of the first filter material.

The first filter medium may be formed to have a bone angle of +15° to +35°, and the second filter material may be formed to have a bone angle of -20° to +25°.

The external air conditioner disclosed in the present invention includes a filter for receiving external air and filtering dust contained in the external air; a temperature control coil disposed downstream of the filter based on air flow and heating or cooling the air passing through the filter; a fan disposed downstream of the temperature control coil based on air flow; an eliminator disposed between the temperature control coil and the fan based on air flow; and an atomizer disposed above the eliminator to inject moisture toward the eliminator so that the material to be absorbed contained in the air passing through the eliminator is absorbed into the eliminator. The eliminator includes a first filter medium and a second filter medium having a wavy shape that removes the material to be absorbed from the air and allows it to be absorbed into moisture, and the first filter medium and the second filter medium are provided in plurality in the direction of air flow. are alternately arranged along a direction intersecting with each other, and the length of the first filter medium and the length of the second filter medium are formed to be different from each other in the flow direction of the air.

The effects of the present invention obtained through the above solutions are as follows.

The first filter medium and the second filter medium included in the eliminator of the present invention are alternately arranged along a direction crossing the air flow direction, and the length of the first filter medium and the second filter medium are formed to be different from each other. The first filter material and the second filter material are formed to have bone angles in different ranges.

According to this structure, it is possible to reduce the ratio of water scattering to the downstream side of the eliminator. Fan failure can be minimized by reducing the rate at which water splashes downstream.

In addition, according to this structure, it is possible to improve the dryness of the front part of the eliminator by reducing the ratio of scattering water to the rear part and increasing the ratio of scattering water to the front part.

The first filter medium and the second filter medium of the eliminator are alternately arranged along a direction crossing the air flow direction, and the first filter medium and the second filter medium are formed to have different bone angles, and the bone angles As is selected within an appropriate range, the differential pressure of the eliminator can be reduced, thereby increasing the filter replacement cycle and reducing fan energy consumption.

1 is a perspective view showing the configuration of an external air conditioner in which an eliminator is installed.
2 is a plan view showing the configuration of an external air conditioner in which an eliminator is installed.
3 is a perspective view illustrating the structure of an eliminator;
4 is an exploded and assembled perspective view illustrating an arrangement state of a first filter medium and a second filter medium of an eliminator;
5A and 5B are side views of a first filter medium and a second filter medium of an eliminator;
6 is a graph showing the results of an eliminator pressure differential evaluation experiment according to bone angles of a first filter material and a second filter material.

Hereinafter, the eliminator 110 of the present invention, the water showering system (WSS) 100 having the eliminator 110, and the outdoor unit 10 having the water showering system (WSS) 100 ) will be described in more detail with reference to the drawings.

1 is a perspective view showing the configuration of the outdoor air conditioner 10 in which the eliminator 110 is installed, and FIG. 2 is a plan view showing the configuration of the outdoor air conditioner 10 in which the eliminator 110 is installed.

1 and 2, when the outdoor air conditioner 10 is inappropriate to recirculate the air because the humidity of the indoor air is very high or it is contaminated with dust, polluted gas, and smell, the indoor air is 100% It refers to a device that exhausts outside, draws in outside air, purifies it, adjusts the temperature and humidity, and then supplies it to the room (clean room, CR). The outer air conditioner 10 includes P/F (PRE FILTER) (200), M/F (MEDIUM FILTER) (250), PH/C (PRE Heating COIL) (300), C/C (COOLING COIL) (350) , H/C (HEATING COIL) (400), WSS (WATER SHOWERING SYSTEM) (100), RH/C (RE HEATING COIL) (450), HU (HUMIDIFIER) (550), FAN (500), C/F (CHEMICAL FILTER) 600, H/F (HEPA FILTER) 650, and the like.

Therefore, when the outdoor air conditioner 10 is operated, the outside air (AIR) is sucked through the air inlet on one side of the outdoor air conditioner 10, and the P/F (PRE FILTER) 200, M/F (MEDIUM FILTER) ) (250), PH / C (PRE HEATING COIL) (300), C / C (COOLING COIL) (350), H / C (HEATING COIL) (400) filtering and temperature control. Then, as the air passes through the WATER SHOWERING SYSTEM (WSS) 100, most gaseous pollutants, that is, NH3, SOx, NOX, Br, Cl, F, organic acids, etc. are removed from the air, and RH/C (RE HEATING COIL) 450 and HU (HUMIDIFIER) 550 are reheated and rehumidified. The purified and temperature-humidified air is sucked through the fan (500) and sent to the C/F (CHEMICAL FILTER) (600) and H/F (HEPA FILTER) (650), where it is purified once more and introduced into the room. .

The P/F (PRE FILTER) 200 and M/F (MEDIUM FILTER) 250 of the outdoor air conditioner 10 are the outermost filters, and are filters that filter out relatively large dust first, and are high-performance filters to be released later. can protect and prolong its lifespan.

PH/C (PRE HEATING COIL) (300), C/C (COOLING COIL) (350), and H/C (HEATING COIL) (400) of the outdoor air conditioner (10) are P/F ( PRE FILTER) 200 and M/F (MEDIUM FILTER) 250 are arranged next. The air that has passed through the P/F (PRE FILTER) (200) and M/F (MEDIUM FILTER) (250) is transferred to the temperature control coil, that is, PH/C (PRE HEATING COIL) (300) and C/C (COOLING COIL) 350 and H/C (HEATING COIL) 400 can heat or cool to control the temperature.

PH/C (PRE HEATING COIL) (300) can prevent the COIL from freezing in winter by raising the outdoor temperature.

The C/C (COOLING COIL) 350 can protect the coil by lowering the outdoor temperature in summer or by circulating cold water in winter to acquire heat.

The H/C (HEATING COIL) 400 can prevent the COIL from freezing in winter by additionally increasing the temperature in the same way that the PH/C (PRE HEATING COIL) 300 raises the outdoor temperature.

A fan (FAN) 500 is disposed on the downstream side of the temperature control coil based on air flow, and humidification can be performed simultaneously by a HUMIDIFIER (HUMIDIFIER) 550.

A water showering system (WSS) 100 is disposed between a temperature control coil and a fan 500, and includes an eliminator 110 and a spray nozzle 120. Water (DI WATER) is sprayed from the top of the eliminator 110 by the injection nozzle 120, and when air passes through the wet eliminator 110, water-soluble gaseous contaminants are removed by contact between gas and liquid. can be removed

The water showering system (WSS) 100 will be described in detail later.

A chemical filter (C/F) 600 is disposed after the fan 500 based on air flow, and may remove molecular contaminants and the like.

H/F (HEPA FILTER) 650 is placed next to C/F (CHEMICAL FILTER) 600 based on air flow, and is a high-performance filter that can filter out most of the extremely fine particles. It is at the level of 0.5㎛, and the HEPA filter can filter out more than 99.97% of particles with a size of 0.3㎛ in the air.

The positions of the filters may vary depending on the design of the outdoor air conditioner 10, and this is not particularly limited in the present invention. However, relatively large dust is removed from the air through the P/F (PRE FILTER) 200 and the M/F (MEDIUM FILTER) 250, and the temperature control coil, that is, the PH/C (PRE HEATING COIL) 300 ), C/C (COOLING COIL) (350), and H/C (HEATING COIL) (400) heat or cool the air to adjust the temperature and send it to the WSS (WATER SHOWERING SYSTEM) (100). , P/F (PRE FILTER) 200 and M/F (MEDIUM FILTER) 250 are disposed, a temperature control coil, and WSS (WATER SHOWERING SYSTEM) 100 are disposed.

Hereinafter, the WATER SHOWERING SYSTEM (WSS) 100 will be described in detail.

FIG. 3 is a perspective view for showing the structure of the eliminator 110, and FIG. 4 is a disassembly and assembly for showing the arrangement of the first filter medium 111 and the second filter medium 112 of the eliminator 110. It is a perspective view.

Referring to FIGS. 3 and 4, the WATER SHOWERING SYSTEM (WSS) 100 includes a spray nozzle 120 capable of spraying water and an eliminator 110 receiving water sprayed from the spray nozzle 120. do.

The eliminator 110 includes a first filter medium 111, a second filter medium 112, and the first filter medium (which receives water sprayed from the injection nozzle 120 and absorbs the material to be absorbed from the air into moisture). 111) and a frame 113 to which the second filter medium 112 can be mounted.

The exterior of the eliminator 110 may form a box shape of a hexahedron, and the frame 113 is disposed along the edge of the hexahedron. The first filter medium 111 and the second filter medium 112 are disposed within an area defined by the frame 113 . Except for the corners of the hexahedron, the rest of the area is open to allow air and water to flow.

The first filter medium 111 and the second filter medium 112 are provided in plurality and are alternately arranged along a direction crossing the flow direction of air. Here, the flow direction of air refers to a direction in which air flows along the air flow path formed in the outdoor air conditioner 10, and may be a horizontal direction. Also, the crossing direction may refer to a normal direction to the flow direction of the air, and may also be a horizontal direction. However, the horizontal direction or the normal direction here does not limit a precise angle in a physical sense, but is a concept that includes a range of predetermined angles close to the horizontal direction or the normal direction.

The first filter medium 111 and the second filter medium 112 are composed of an appropriate combination of absorbent plates formed by molding an absorbent material into a plate shape, and are formed by overlapping and connecting multiple layers of wavy plate materials or varying the angle of the wavy shape in various ways. transformation can be carried out. As an example of an absorbent material, the first filter medium 111 and the second filter medium 112 may be formed of a ceramic material or a PET material, but are not necessarily limited thereto and may be selected according to need. In addition, the first filter medium 111 and the second filter medium 112 have a structure in which wavy wrinkles are formed on a polygonal plate such as a square. Wavy shape refers to a structure in which peaks and valleys are alternately and repeatedly arranged. Waves are formed on both sides of the first filter medium 111 and the second filter medium 112, and when mountains are formed on one surface of each filter medium, valleys are naturally formed on the other surface.

A peak or valley has a shape extending along one direction. Here, an angle between a flow direction of air and an extension direction of peaks or valleys forming a wavy shape may be defined as an oblique angle or a valley angle.

The wavy shape or peaks and valleys may coincide with the air flow direction based on the air flow, but may be inclined in an oblique direction. For example, assuming that air flows in a horizontal direction from an upstream side to a downstream side of the eliminator 110, mountains or valleys may extend in a direction inclined with respect to the horizontal direction.

In addition, the first filter medium 111 and the second filter medium 112 receive water from the spray nozzle 120 on the upper side, and the water flows downward along the surfaces of the first filter medium 111 and the second filter medium 112. drained and drained When air passes between the first filter medium 111 and the second filter medium 112 in a state where the first filter medium 111 and the second filter medium 112 are wet with water, gas-liquid contact occurs, and water-soluble gas phase Contaminants are removed from the air.

The first filter medium 111 and the second filter medium 112 are distinguished from each other by size and bone angle. The size of the first filter medium 111 and the second filter medium 112, and the bone angle of the first filter medium 111 and the second filter medium 112 may cause water scattering, drying of each filter medium, and eliminator 110 is a major factor in determining the foreclosure of

The peaks or valleys formed in the first filter medium 111 extend obliquely upward from the front end to the rear end of the first filter medium 111 . Here, the front end (front end) or front (front part) of the first filter medium 111 means a position where air is supplied from the first filter medium 111, or a position where air is introduced when air passes through the first filter medium 111. point to the location The portion of the first filter medium 111 visible when looking at the eliminator 110 from the H/C 400 with reference to FIGS. 1 and 2 corresponds to the front end or front surface of the first filter medium 111 . Conversely, the rear end (rear end) or rear end (rear part) of the first filter medium 111 means a position where air is discharged from the first filter medium 111, or a position where air is discharged when air passes through the first filter medium 111. points to 1 and 2, the part of the first filter medium 111 that is visible when looking at the eliminator 110 from the RH/C 450 corresponds to the rear end or rear surface of the first filter medium 111.

When the peaks or valleys formed in the first filter material 111 extend in an oblique direction from the front end to the rear end of the first filter material 111, the first filter material 111 has a positive bevel angle or a positive bone angle. can be defined as having

In contrast, peaks or valleys formed in the second filter medium 112 extend in a direction different from that of the first filter medium 111 . For example, the peaks or valleys formed in the second filter medium 112 may extend in an oblique direction upward, horizontally, or downward from the front end to the rear end of the second filter medium 112. The angularity or bone angle of the second filter material 112 has a different value from the angularity or bone angle of the first filter material 111 .

In this way, in the eliminator 110, the wave-shaped first filter medium 111 and the second filter medium 112 arranged adjacently cross each other at an angle, so that gaseous contaminants flowing in a straight line do not pass through and bump into each other in an inclined direction so that the inclined flow occurs. It is configured to be filtered and dropped while doing so.

Hereinafter, with reference to FIGS. 3 to 5B , scattering of water according to the size of the first filter medium 111 and the second filter medium 112 and the bone angle of the first filter medium 111 and the second filter medium 112, each The drying phenomenon of the filter medium and the differential pressure of the eliminator 110 will be described.

5A is a side view of the first filter medium 111 of the sheet, and FIG. 5B is a side view of the second filter medium 112 of the sheet.

First, when comparing the sizes of the first filter medium 111 and the second filter medium 112, the thicknesses of the first filter medium 111 and the second filter medium 112 are the same within the tolerance range, and the first filter medium 111 ) and the height of the second filter medium 112 are also the same within the tolerance range, while the length L1 of the first filter medium 111 and the length L2 of the second filter medium 112 are formed differently from each other in the air flow direction. do.

In the present invention, the length of the first filter medium 111 is longer than the length of the second filter medium 112 so that the specific gravity of water scattered to the front and rear (or upstream and downstream) of the eliminator 110 can be adjusted. do. In the flow direction of air, the front end of the first filter medium 111 and the front end of the second filter medium 112 are formed at the same position. Accordingly, since the length of the first filter medium 111 is formed longer than the length of the second filter medium 112 in the air flow direction, the rear end of the first filter medium 111 in the air flow direction is of the eliminator 110. It protrudes more than the rear end of the second filter medium 112 towards the rear (downstream side). In addition, at the rear end of the first filter medium 111, the adjacent first filter mediums 111 face each other.

The difference between the length of the first filter medium 111 and the length of the second filter medium 112 in the flow direction of the air affects the specific gravity of water scattered to the front and rear of the eliminator 110 .

As the difference gradually decreases and the length of the first filter medium 111 and the length of the second filter medium 112 become similar, the specific gravity of water scattered to the rear of the eliminator 110 increases. In this case, moisture flows into the fan disposed at the rear of the eliminator 110 and causes a failure.

Conversely, if the length of the first filter medium 111 is excessively long and the length of the second filter medium 112 is excessively short, if the difference becomes too large, the specific gravity of water scattered to the rear of the eliminator 110 is reduced, but the eliminator Water distribution is biased toward the front end of the water generator 110, and drying occurs at the rear end of the first filter medium 111 and the rear end of the second filter medium 112. Drying of the first filter medium 111 and the second filter medium 112 substantially causes the function of the eliminator 110 to deteriorate.

Therefore, the length of the first filter medium 111 and the length of the second filter medium 112 should be selected within an appropriate range in consideration of the above points. When the eliminator 110 is divided in half in the air flow direction, the proper ratio of the water distributed to the front part and the water distributed to the rear part of the eliminator 110 is front: rear = 7 or more: 3 below

Expressing the appropriate range numerically, the length from the front end to the rear end of the second filter medium 112 in the air flow direction is preferably 75 to 98% of the length from the front end to the rear end of the first filter medium 111, , more preferably 80 to 93%. Since the length of the first filter medium 111 and the length of the second filter medium 112 are designated as a ratio, when the length of the first filter medium 111 increases, the length of the second filter medium 112 also increases, but the second filter medium ( 112) has a length within the above ratio range with respect to the length of the first filter medium 111.

In addition, the length from the front end to the rear end of the second filter medium 112 in the air flow direction is shorter than the length from the front end to the rear end of the first filter medium 111 by 8 mm or more. Since this value is an absolute value, it means that the minimum length difference between the two filter media must be 8 mm or more regardless of the relative lengths of the first filter media 111 or the second filter media 112.

For example, if the length from the front end to the rear end of the first filter medium 111 in the air flow direction is 50 mm to 400 mm, the length from the front end to the rear end of the second filter medium 112 is 75 to 98 mm from 50 mm to 400 mm. % length. As the length of the first filter medium 111 increases, the ratio of the length of the second filter medium 112 based on the length of the first filter medium 111 increases, and conversely, the length of the second filter medium 112 decreases. As the length increases, the ratio of the length of the second filter medium 112 to the length of the first filter medium 111 may decrease.

For example, when the length from the front end to the rear end of the first filter medium 111 is 50 mm or more and 200 mm or less, the length from the front end to the rear end of the second filter medium 112 is the length of the first filter medium 111 from the front end to the rear end. 75 to 95%, and when the length from the front end to the rear end of the first filter medium 111 is greater than 200 mm and less than 400 mm, the length from the front end to the rear end of the second filter medium 112 is from the front end to the rear end of the first filter medium 111 It can be selected as 90 to 98% of the length up to.

While maintaining a length difference of 8 mm or more between the first filter medium 111 and the second filter medium 112, considering the possibility of scattering and drying within the above numerical range, the The relative distance is chosen.

Therefore, the length of the second filter medium 112 varies according to the length of the first filter medium 111, but the length of the second filter medium 112 is shorter than the length of the first filter medium 111 is the same in any case. do.

Next, the effect of the angle of elevation or the angle of valley between the first filter medium 111 and the second filter medium 112 on scattering, drying, and differential pressure of water will be described.

As described above, the angle between the air flow direction and the extension direction of the crests or valleys forming the wavy shape of the first filter material 111 or the second filter material 112 is defined as a peak angle or a valley angle. In FIG. 5A, θ1 represents the angle of angularity of the first filter material 111 or the angle of the bone of the first filter material 111, and in FIG. represents an angle.

In addition, if the peaks or valleys formed in the first filter medium 111 and the second filter medium 112 extend in a direction inclined upward from the front end to the rear end of the first filter medium 111 or the second filter medium 112, Deviation or bone angle is defined as positive divergence or positive bone angle.

Conversely, if the peaks or valleys formed in the first filter medium 111 and the second filter medium 112 extend in a direction inclined downward from the front end to the rear end of the first filter medium 111 or the second filter medium 112, An angle or bone angle is defined as a negative divergence or negative bone angle.

Based on this definition, the first filter medium 111 and the second filter medium 112 are formed to have different bone angles. While the first filter material 111 always has a positive bone angle, the second filter material 112 may have a positive bone angle, a negative bone angle, or a 0 bone angle. This means that the flow direction and the bone angle of the second filter medium 112 are parallel. As the bone angle of the first filter medium 111, which always has a positive bone angle, increases, the possibility of water scattering to the rear of the eliminator 110 decreases, but the differential pressure of the eliminator 110 increases, so that the fan will increase energy consumption. Conversely, as the bone angle of the first filter medium 111 decreases in a range greater than 0, the differential pressure of the eliminator 110 decreases, but the possibility of water scattering to the rear of the eliminator 110 increases do.

Therefore, the bone angle of the first filter material 111 should be selected as an appropriate value within the range considering the possibility of scattering and the change in differential pressure, and in the present invention, the bone angle of the first filter material 111 is +15 to +35° It is preferably set to , and more preferably it can be set to +20 to +30 °.

The absolute value of the bone angle of the second filter material 112 is always smaller than the absolute value of the bone angle of the first filter material 111 . At this time, as the absolute value of the bone angle of the second filter medium 112 having a positive bone angle increases, the specific gravity of the water distributed to the rear end of the eliminator 110 decreases, causing drying of the rear end. Conversely, as the absolute value of the bone angle of the second filter material 112 having a negative bone angle increases, that is, as the bone angle of the second filter material 112 increases in the negative direction, the rear end of the eliminator 110 The specific gravity of the water to be distributed increases, causing drying of the front end.

Therefore, the bone angle of the second filter medium 112 must be specified within an appropriate range so that excessive tilting does not occur at the front and rear ends of the eliminator 110 . The bone angle of the second filter material 112 may be designated as a relative value compared to that of the reference fabric, that is, the bone angle of the first filter material 111, or may be designated as an absolute value regardless of the bone angle of the first filter material 111. It could be.

When designated as a relative value, the bone angle of the second filter material 112 may be set to +70% to -70% of the bone angle of the first filter material 111, preferably +64% to -64% . When the bone angle of the second filter material 112 exceeds +70%, the possibility of drying out of the rear end of the eliminator 110 increases, and the bone angle of the second filter material 112 is greater than -70%. It has been described above that the possibility of drying out of the front end of the eliminator 110 increases when it deviates to a large negative value.

As such, the absolute value of the bone angle of the second filter material 112 may always be smaller than the absolute value of the bone angle of the first filter material 111 .

When specified as an absolute value, the bone angle of the second filter material 112 may be set to -20 to +25°, preferably -15 to +20°. If the bone angle of the second filter material 112 is greater than +25 °, the possibility of drying out of the rear end of the eliminator 110 increases, and if the bone angle of the second filter material 112 is less than -20 °, That is, as described above, when the bone angle of the second filter medium 112 is greater than -20° to a negative value, the possibility of drying out of the front end of the eliminator 110 increases.

Hereinafter, experimental results obtained by evaluating scattering, drying, differential pressure, and the like while changing the bone angles of the first filter medium 111 and the second filter medium 112 will be described.

The setting criteria of the experimental examples are as follows, and the differential pressure and scattering were evaluated for each experimental example.

Experimental example Bone angle of the first filter material Bone angle of the second filter material One +30° -30° 2 +30° +15° 3 +30° -15° 4 +30° 0° 5 +15° -15° 6 +15° 0°

First, the results of evaluating the differential pressure for the samples of Experimental Examples 1 to 6 are shown in FIG. 6 . FIG. 6 is a graph showing results of an experiment for evaluating differential pressure of the eliminator 110 according to bone angles of the first filter medium 111 and the second filter medium 112 .

The horizontal axis of the graph corresponds to the wind speed of the outdoor air conditioner 10, and the vertical axis of the graph corresponds to the differential pressure of the eliminator 110.

The design standard wind speed of the outdoor air conditioner 10 can be said to be about 3 m/s. Comparing Experimental Examples 1 to 4, the differential pressure in Experimental Example 1 is about 8.5 mmAq, whereas in Experimental Examples 2 to 4 it is higher than that. It can be seen that a low differential pressure was recorded. Therefore, looking at these experimental examples, it is preferable that the absolute value of the bone angle of the second filter material 112 is lower than the absolute value of the bone angle of the first filter material 111 . However, in Experimental Example 5 and Experimental Example 6, different results from the previous results were derived.

Next, the results of whether scattering occurred in the body of the eliminator 110 are shown in Table 2 below, and the distribution ratio of water was divided into the front end and the rear end of the eliminator 110 and displayed together.

Experimental Example Eliminator (110) body scattering Shear part distribution rate (%) Distribution rate at the rear end (%) One does not occur 40 60 2 does not occur 97 3 3 does not occur 78 22 4 does not occur 96 4 5 Occur 36 64 6 Occur 82 18

When Experimental Examples 1 to 4 are compared with Experimental Examples 5 to 6 in Table 2, it can be seen that the possibility of scattering increases as the bone angle of the first filter medium 111 decreases. In addition, it can be seen that as the bone angle of the second filter material 112 increases to a positive value, more water is distributed to the front end of the eliminator 110, and conversely, the bone angle of the second filter material 112 becomes negative. As the value increases, it can be seen that more water is distributed to the rear end of the eliminator 110.

As described above, scattering, drying, and differential pressure according to the size and bone angle of the first filter medium 111 and the second filter medium 112 can be adjusted.

The eliminator described above, the water showering system including the eliminator, and the outdoor air conditioner including the water showering system are not limited to the configuration and method of the above-described embodiments, but the embodiments All or part of each embodiment may be selectively combined and configured so that various modifications can be made.

Claims (10)

A first filter medium and a second filter medium having a wavy shape for receiving moisture and allowing the target material to be absorbed in moisture to remove the target material from the air;
The first filter medium and the second filter medium are provided in plurality and are alternately arranged with each other along a direction crossing the flow direction of air,
The eliminator in which the length of the first filter medium and the length of the second filter medium are formed to be different from each other in the flow direction of the air. According to claim 1,
Peaks and valleys forming the wavy shape are alternately and repeatedly formed in the first filter medium and the second filter medium,
The peaks or valleys formed in the first filter medium extend in an oblique direction toward the upper side from the front end to the rear end of the first filter medium,
The eliminator in which the length of the first filter medium is formed longer than the length of the second filter medium in the flow direction of the air. According to claim 1,
The front end of the first filter medium and the front end of the second filter medium are formed at the same position in the flow direction of the air,
The rear end of the first filter medium protrudes more than the rear end of the second filter medium toward the rear of the eliminator in the flow direction of the air. According to claim 3,
The length from the front end to the rear end of the second filter medium in the flow direction of the air is 75 to 98% of the length from the front end to the rear end of the first filter medium. According to claim 3,
The length from the front end to the rear end of the second filter medium in the flow direction of the air is shorter than the length from the front end to the rear end of the first filter medium by 8 mm or more. According to claim 3,
The length from the front end to the rear end of the first filter medium in the flow direction of the air is 50 mm to 400 mm,
When the length from the front end to the rear end of the first filter material is 50 mm or more and 200 mm or less, the length from the front end to the rear end of the second filter material is 75 to 95% of the length from the front end to the rear end of the first filter material,
When the length from the front end to the rear end of the first filter material is greater than 200 mm and less than or equal to 400 mm, the length from the front end to the rear end of the second filter material is 90 to 98% of the length from the front end to the rear end of the first filter material. . According to any one of claims 1 to 6,
The angle between the flow direction of the air and the extension direction of the peaks or valleys forming the wavy shape is defined as a bone angle,
When the peaks or valleys formed in the first filter material or the second filter material extend in an inclined direction from the front end to the rear end of the first filter material or the second filter material, the bone angle is defined as a positive bone angle. become,
When the peaks or valleys formed in the first filter material or the second filter material extend in an inclined direction from the front end to the rear end of the first filter material or the second filter material, the bone angle is defined as a negative bone angle. becomes,
The first filter material and the second filter material are formed to have different bone angles,
The absolute value of the bone angle of the second filter material is smaller than the absolute value of the bone angle of the first filter material. According to claim 7,
The first filter medium is formed to have a positive bone angle,
The second filter material is formed to have a bone angle corresponding to +70% to -70% of the bone angle of the first filter material. According to claim 7,
The first filter medium is formed to have a bone angle of +15° to +35°,
The second filter medium is an eliminator formed to have a bone angle of -20 ° to +25 °. A filter for receiving outdoor air and filtering dust contained in the outdoor air;
a temperature control coil disposed downstream of the filter based on air flow and heating or cooling the air passing through the filter;
a fan disposed downstream of the temperature control coil based on air flow;
an eliminator disposed between the temperature control coil and the fan based on air flow; and
A sprayer disposed above the eliminator and spraying moisture toward the eliminator so that the material to be absorbed contained in the air passing through the eliminator is absorbed into the eliminator;
The eliminator includes a first filter medium and a second filter medium having a wavy shape for receiving moisture and allowing the target material to be absorbed in moisture to remove the target material from the air,
The first filter medium and the second filter medium are provided in plurality and are alternately arranged with each other along a direction crossing the flow direction of air,
The outdoor air conditioner in which the length of the first filter medium and the length of the second filter medium are formed to be different from each other in the flow direction of the air.

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