KR102436261B1 - Evaporative cooler - Google Patents

Abstract

The evaporative cooler includes: a heat exchange unit having an inlet through which air is introduced and an outlet through which air is discharged; an air transport unit for supplying water to the heat exchange unit so that the air introduced into the heat exchange unit through the inlet is cooled by the water supplied to the heat exchange unit and then discharged through the outlet; a storage unit for storing water to be supplied from the air transport unit to the heat exchange unit; And in order to sterilize the bacteria contained in the water, it includes a sterilizing unit for generating a sterilizing material from the water.

Description

Evaporative Cooler {EVAPORATIVE COOLER}

The present invention relates to an evaporative cooler.

In general, cooling devices for cooling air use a refrigerant, and the refrigerant is recognized as the main culprit of ozone layer depletion and global warming. Accordingly, recently, an evaporative cooler that performs cooling using latent heat generated during evaporation of water has been used.

In order to perform cooling through the evaporative cooler, it is necessary to continuously supply water to be evaporated, and the water may be stored in a tank or the like and used in a continuously circulating manner. However, if the supplied water is contaminated, the biofilm may adhere to the tank and the area where heat exchange is performed due to evaporation. In addition, the adhered bacteria may also affect the evaporation amount of water, thereby reducing heat exchange efficiency, and may cause a bad odor due to the contaminated water.

An object of the present invention is to provide an evaporative cooler capable of easily and safely removing foreign substances in circulating water.

In an example, the evaporative cooler includes a heat exchange unit having an inlet through which air is introduced and an outlet through which the air is discharged, and after the air introduced into the heat exchange unit through the inlet is cooled by the water supplied to the heat exchange unit, the A sterilization material is generated from the air transport unit supplying water to the heat exchange unit so as to be discharged through the outlet, a storage unit storing water to be supplied from the air transport unit to the heat exchange unit, a sterilization tank storing sterilization water, and water stored in the sterilization tank. It has a sterilization terminal for allowing the water stored in the sterilization tank to become the sterilization water, and to sterilize bacteria contained in the water stored in the storage unit, sterilization water containing the sterilization material is generated from the water stored in the sterilization tank. a sterilization unit, a pump for pumping the water stored in the storage unit to the air transport unit so that the water is supplied from the air transport unit, a control unit controlling the operation of the pump and the sterilization unit, and connecting the storage unit and the air transport unit, and the pump a first flow path in which is disposed, and a second flow path connecting a portion located upstream of the pump among the first flow paths and the sterilization unit, wherein the control unit is configured such that the control unit is connected to a power source and the evaporative cooler is operated When the power button is selected, control is performed so that the sterilization unit operates first before the operation of the pump, and when the pump is operating, the sterilization unit is controlled so that the sterilization unit does not operate, and when water is supplied to the sterilization tank, the After supplying power to the sterilization terminal for a predetermined time to maintain the state in which the sterilization water is stored in the sterilization tank, when the pump operates, the water stored in the storage unit is pressurized to the air transport unit through the first flow path, and the sterilization By pressurizing the sterilizing water stored in the tank to the air transport unit through the first flow path through the second flow path, a control can be performed so that the sterilizing material sterilizes bacteria contained in the water pumped to the air transport unit.

In another example, the evaporative cooler includes a heat exchange unit having an inlet through which air is introduced and an outlet through which air is discharged; an air transport unit for supplying water to the heat exchange unit so that the air introduced into the heat exchange unit through the inlet is cooled by the water supplied to the heat exchange unit and then discharged through the outlet; a storage unit for storing water to be supplied from the air transport unit to the heat exchange unit; and a sterilizing unit for generating sterilizing water containing a sterilizing material and mixing it with water in order to sterilize the bacteria contained in the water, wherein the sterilizing unit includes a sterilizing tank in which the sterilizing water is stored, and a sterilizing material from the water stored in the sterilizing tank. It has a sterilization terminal that generates a sterilization tank and turns the water stored in the sterilization tank into sterilization water.

According to the present invention, since the sterilization unit can sterilize the bacteria contained in the water by generating a sterilizing material from the water, it is possible to remove the bacteria in the water very simply and safely.

1 schematically shows an evaporative cooler according to Embodiment 1 of the present invention.
2 is a conceptual view of an evaporative cooler according to a second embodiment of the present invention.
3 is a conceptual view of an evaporative cooler according to a modification of the present invention.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. In adding reference numerals to the components of each drawing, it should be noted that the same components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, in the description of the embodiment of the present invention, if it is determined that a detailed description of a related known configuration or function interferes with the understanding of the embodiment of the present invention, the detailed description thereof will be omitted.

Structure of evaporative cooler

Example One

1 schematically shows an evaporative cooler according to Embodiment 1 of the present invention. Hereinafter, an evaporative cooler according to Embodiment 1 of the present invention will be described with reference to FIG. 1 .

Referring to FIG. 1 , the evaporative cooler according to the first exemplary embodiment of the present invention includes a heat exchange unit 10 , an air transport unit 20 , a storage unit 30 , and a sterilization unit 40 .

First, the heat exchange unit 10 includes an inlet 11 through which air is introduced and an outlet 19 through which the air introduced through the inlet 11 is discharged. The air introduced through the inlet 11 may be cooled by heat exchange with water to be described later, and then discharged through the outlet 19 . The internal structure of the heat exchange unit 10 is not particularly limited.

The air transport unit 20 supplies water to the heat exchange unit 10 . As the water supplied from the air transport unit 20 to the heat exchange unit 10 is evaporated, latent heat of evaporation is generated, and the air introduced through the inlet 11 is cooled by the latent heat of evaporation and then discharged through the outlet 19. have.

At this time, the air-receiving unit 20 may supply water to the heat exchange unit 10 in the form of spraying in order to improve the cooling effect according to evaporation.

In addition, the water supplied from the air receiving unit 20 may be directly supplied to the air discharged through the outlet 19 to discharge the cooled air, depending on the internal structure of the heat exchange unit 10 , or the outlet 19 . After cooling the air flowing in the flow path adjacent to the flow path of the air discharged through the , the cooled air may be allowed to cool the air discharged through the outlet 19 again.

The storage unit 30 stores water to be supplied from the air transport unit 20 . As shown in FIG. 1 , the evaporative cooler according to Embodiment 1 of the present invention includes a pump 25 that pumps water stored in the storage unit 30 to the airlift unit 20 so that water is supplied from the airlift unit 20 . may include more. The water stored in the storage unit 30 may be supplied to the heat exchange unit 10 by being pressurized to the air transport unit 20 when the pump 25 operates.

In this case, the air-lift unit 20 may be provided on the upper side of the heat exchange unit 10 , and the storage unit 30 may be provided on the opposite side of the air-lift unit 20 with the heat exchange unit 10 interposed therebetween. That is, water that is not evaporated by the heat exchange unit 10 among the water supplied from the air transport unit 20 may be recovered to the storage unit 30 again. The water recovered to the storage unit 30 may be supplied to the air transport unit 20 again.

In this way, the water may be repeatedly used while circulating the storage unit 30 , the air transport unit 20 , and the heat exchange unit 10 . However, if bacteria are generated in the circulating water, the above-mentioned problems such as the formation of a biofilm in the water circulating path may occur.

The sterilization unit 40 is to solve this problem, and in order to sterilize the bacteria contained in the water, a sterilizing material is generated from the water. That is, since the sterilization unit 40 can generate a sterilizing material from water without separately injecting a chemical material for sterilization, it is environmentally friendly, harmless to the human body, and can easily and economically remove bacteria.

More specifically, the sterilization unit 40 may oxidize chlorine ions (Cl ⁻ ) in water to chlorine (Cl ₂ ) to generate a sterilizing material. When chlorine ions (Cl ^- ) are oxidized to chlorine (Cl ₂ ), they can be immediately dissolved in water and converted into hypochlorous acid (HOCl). Hypochlorous acid (HOCl) is a sterilizing substance that can sterilize bacteria.

As such, the sterilization unit 40 oxidizes chlorine ions (Cl ⁻ ) to chlorine (Cl ₂ ) in order to generate hypochlorous acid (HOCl). can When power is supplied to the sterilization terminal 45 , the sterilization terminal 45 may oxidize chlorine ions (Cl ⁻ ) in water to chlorine (Cl ₂ ). In addition, a platinum group metal oxide (not shown) that acts as a catalyst when oxidizing chlorine ions (Cl ⁻ ) into chlorine (Cl ₂ ) may be coated on the outer surface of the sterilization terminal 45 . The platinum group metal oxide may serve as a catalyst by lowering the potential difference when chlorine ions (Cl ⁻ ) are oxidized to chlorine (Cl ₂ ).

The platinum group metal oxide may be produced by coating the platinum group metal on the sterilization terminal 45 and then heating it at a high temperature to oxidize the platinum group metal, and as the platinum group metal, for example, platinum, iridium, ruthenium, etc. may be used.

Meanwhile, the sterilization unit 40 may be provided inside the storage unit 30 . In addition, a control unit (not shown) that controls the operation of the pump 25 and the sterilization unit 40 may control the sterilization unit 40 so that the sterilization unit 40 does not operate when the pump 25 is operating. That is, since water is circulating when the pump 25 is in operation, the efficiency may be lowered when the sterilizing material is generated by the sterilizing unit 40 . Therefore, the sterilizing unit 40 provided inside the pump 25 generates a sterilizing material when the pump 25 is not operating, that is, when the water is substantially rectifying, and the generated water containing the sterilizing material It may be desirable to have it circulated by a pump 25 .

Also, the controller may control the amount of water stored in the storage unit 30 . More specifically, the control unit may control the amount of water stored in the storage unit 30 to maintain a predetermined volume or more.

As described above, the water that is not evaporated after being supplied from the air transport unit 20 to the heat exchange unit 10 may be recovered back to the storage unit 30 . However, since the water evaporated in the heat exchange unit 10 cannot be recovered to the storage unit 30, the amount of water stored in the storage unit 30 is inevitably reduced. Accordingly, the controller may supply water to the storage unit 30 so that the water stored in the storage unit 30 maintains a predetermined volume or more. On the other hand, the predetermined volume may be selected experimentally.

At this time, the control unit is based on the amount of water supplied from the storage unit 30 to the airlifting unit 20 and the amount of water that is evaporated without being recovered to the storage unit 30 after being supplied from the airlifting unit 20 to the heat exchange unit 10 . The amount of water to be supplied to the storage unit 30 may be determined.

Example 2

2 is a conceptual view of an evaporative cooler according to a second embodiment of the present invention. Hereinafter, an evaporative cooler according to a second embodiment of the present invention will be described with reference to FIG. 2 . The evaporative cooler according to the second embodiment of the present invention is different from the evaporative cooler according to the first embodiment in the position where the sterilizing unit 40 is provided and the basic control method of the sterilizing unit 40 . The same or equivalent reference numerals are assigned to the same or equivalent components as those of the evaporative cooler according to Embodiment 1 of the present invention, and detailed descriptions thereof are omitted.

The sterilization unit 40 of the evaporative cooler according to the second embodiment of the present invention may be provided outside the storage unit 30 . The sterilization unit 40 may include a sterilization tank 41 for accommodating water and a sterilization terminal 45 provided in the sterilization tank 41 .

After the water stored in the storage unit 30 is recovered to the sterilization tank 41 of the sterilization unit 40 , the storage unit 30 together with the sterilization material generated by the sterilization terminal 45 in the sterilization tank 41 . can be re-supplied. In other words, the water stored in the storage unit 30 circulates between the sterilizing unit 40 and the storage unit 30 , so that the water including the sterilizing material is stored in the storage unit 30 .

In addition, the controller may control the sterilizing unit 40 so that the sterilizing unit 40 does not operate when the pump 25 is operating. Here, the operation of the sterilization unit 40 may mean generation of a sterilizing material by the sterilization terminal 45 and circulation of water between the storage unit 30 and the sterilization unit 40 .

When the pump 25 is operating, since water circulates through the air-lift unit 20, the heat exchange unit 10, and the storage unit 30, when the water circulation to the sterilization unit 40 is made at the same time, it does not contain a sterilizing material. There is a possibility that water that is not used may be supplied to the air transport unit 20 . Therefore, when the pump 25 is not operating, the control unit recovers the water stored in the storage unit 30 to the sterilization unit 40 and circulates it to the storage unit 30, while sufficient water stored in the storage unit 30 is supplied. When an amount of the sterilizing material is included, it may be preferable to supply water to the air-lifting unit 20 .

Control method of evaporative cooler

Hereinafter, a method for controlling an evaporative cooler according to Embodiment 1 of the present invention will be described with reference to FIG. 1 . Hereinafter, a control method of the evaporative cooler will be described with reference to FIG. 1 , but substantially the same or substantially the same control method may be applied to the evaporative cooler according to Embodiment 2 of the present invention.

First, when the controller is connected to a power source for use of the evaporative cooler, the user may operate the evaporative cooler through a power button (not shown).

At this time, when the power button is selected by the user, the control unit may perform a control such that the sterilization unit 40 operates first. In other words, when the power button is selected by the user, the sterilization unit 40 may operate immediately so that the sterilization is performed first before the operation of the pump 25 . In addition, the controller may control the sterilizing unit 40 so that the sterilizing unit 40 does not operate when the pump 25 is operating. On the other hand, in the case of the evaporative cooler according to the second embodiment of the present invention (see FIG. 2 ), the operation of the sterilization unit 40 means the generation and storage of a sterilizing material by the sterilization terminal 45 and the storage unit 30 and the sterilization unit 40 . ) can mean the circulation of water between

If the pump 25 operates to circulate and supply water, it may not be easy to generate a sterilizing material. Therefore, when the user presses the power button to operate the evaporative cooler, it may be preferable that the sterilization unit 40 operates immediately to perform sterilization first. When the sterilization unit 40 operates to sufficiently generate a sterilizing material, the pump 25 may operate to start circulating and supplying water.

In this case, the sterilization unit 40 may repeat operation and stop at predetermined time intervals. Since the sterilizing material may remain in water for a predetermined time once it is generated, it may not be necessary to continuously generate the sterilizing material. Accordingly, the control unit may control the sterilization unit 40 so that the sterilization unit 40 operates for a predetermined time to generate a sterilizing material and stops the operation for a predetermined time period.

That is, when the evaporative cooler is operated, after the sterilization unit 40 operates first, the sterilization unit 40 may stop the operation and the pump 25 may operate. After that, when a predetermined time elapses, the sterilizing unit 40 may operate again to generate a sterilizing material.

And the operating time, which is the time interval for the sterilization unit 40 to repeat operation and stop, and the time for operating the sterilization unit 40 by supplying power to the sterilization terminal 45 and the sterilization terminal 45, the amount of water, TDS (total dissolved solid matter), the area in which the sterilization terminals 45 come into contact with water, the number of the sterilization terminals 45 , and the spacing between the sterilization terminals 45 may be determined based on at least one of the spaced apart intervals.

More specifically, if the amount of water is large, since the volume of the area where the sterilizing substance should act may be large, a large amount of the sterilizing substance may be required. Therefore, when the amount of water is increased, the operating time of the sterilizing unit 40 is increased, but the interval of a predetermined time for repeating the operation and the stop may be decreased.

In addition, the high TDS of water means that the concentration of ions included in the water is high, and thus the concentration of chlorine ions (Cl ⁻ ) in water may also be high. That is, if the TDS of water is high, the concentration of chlorine ions (Cl ⁻ ) reacting with the sterilization terminal 45 may also be high, so the operation time of the sterilization unit 40 is reduced, and the interval of a predetermined time for repeating operation and stopping is It may be desirable to increase

On the other hand, a low TDS of water may mean that the concentration of chlorine ions (Cl ⁻ ) in water is low ^. can Therefore, it may be desirable to increase the operating time of the sterilizing unit 40 to generate a sufficient amount of the sterilizing material, and to decrease the interval of a predetermined time for repeating operation and stopping.

In addition, if the area in which the sterilization terminal 45 and water are in contact is large, the area where chlorine ions (Cl ⁻ ) and the sterilization terminal 45 react may also be large, so the area in which the sterilization terminal 45 and water are in contact is wide. In this case, a sufficient amount of sterilizing material can be produced in a short time. Therefore, it may be desirable to reduce the operating time of the sterilization unit 40 and increase the interval of a predetermined time for repeating the operation and the stop.

In addition, since a relatively large amount of sterilizing material can be generated at the same time when the number of sterilization terminals 45 is large, the operation time decreases as the number of sterilization terminals 45 increases, and a predetermined time for repeating operation and stopping It may be desirable to increase the interval of .

In addition, as the spacing between the sterilization terminals 45 is narrower, the time for which chlorine ions (Cl ⁻ ) and the sterilization terminal 45 react by electrolysis may be shortened. In addition, when the other conditions are the same, as the interval between the sterilization terminals 45 is narrower, the concentration of the sterilizing material is higher, and thus the time required for sterilization may be shortened. Therefore, when the interval between the sterilization terminals 45 is narrow, it may be desirable to decrease the operation time and increase the interval of a predetermined time for repeating operation and stopping.

Meanwhile, the amount of the sterilizing material generated by the sterilizing terminal 45 may be adjusted by controlling the amount of power supplied to the sterilizing terminal 45 . That is, the control unit can control the amount of power supplied to the sterilization terminal 45, and as the power supplied increases, the amount of oxidation from chlorine ions (Cl ⁻ ) to chlorine (Cl ₂ ) increases, and accordingly, chlorine ( Cl ₂ ) The amount of hypochlorous acid (HOCl) generated by dissolving in water may increase.

And the size of the power to be supplied to the sterilization terminal 45 to generate the sterilization material is also the amount of water, the TDS of water, the area in contact with the sterilization terminal 45 and water, the number of the sterilization terminals 45 and the sterilization terminal 45 may be determined by the spaced interval of

More specifically, if the amount of water is large, since the volume of the area where the sterilizing substance should act may be large, a large amount of the sterilizing substance may be required. Therefore, when the amount of water increases, the amount of power supplied to the sterilization terminal 45 may also increase.

In addition, when the TDS of water is high, a sufficient amount of the sterilizing material can be generated even if the amount of power to be supplied to the sterilization terminal 45 is reduced. And when the TDS of water is low, it may be preferable to increase the amount of power to be supplied to the sterilization terminal 45 to induce the chlorine ions (Cl ⁻ ) to react sufficiently.

In this case, a reference TDS may be set to determine the degree of low and high TDS of water, and the reference TDS may be experimentally selected and set in the control unit. That is, when the TDS of water is higher than the reference TDS, the control unit reduces the amount of power to be supplied to the sterilization terminal 45, and when the TDS of water is lower than the reference TDS, the amount of power to be supplied to the sterilization terminal 45 can be increased. .

In addition, when the contact area between the sterilization terminal 45 and water is large, the amount of power supplied to the sterilization terminal 45 may be reduced. Conversely, when the contact area between the sterilization terminal 45 and water is narrow, it may be desirable to increase the amount of power supplied to the sterilization terminal 45 to improve the reaction strength.

In addition, as the number of the sterilization terminals 45 is large or the spaced distance between the sterilization terminals 45 is narrow, the amount of power supplied to the sterilization terminals 45 is reduced, and the number of the sterilization terminals 45 is small or the sterilization terminal 45 is small. It may be more efficient to increase the amount of power supplied to the sterilization terminal 45 as the spaced distance between the terminals 45 increases.

When the evaporative cooler is operated according to such a control method and the user stops the operation of the evaporative cooler through the power button, the control unit stops the operation of the pump 25, but the sterilizer 40 operates according to a predetermined operation pattern control can be performed. Of course, in order for the sterilization unit 40 to operate, the state in which the control unit is connected to the power source needs to be maintained.

More specifically, the controller may control the sterilization unit 40 to start the operation at the moment the user presses the power button to stop the operation of the evaporative cooler. By generating a sterilizing material when the use of the evaporative cooler is finished, when the evaporative cooler is to be used again later, even if the operation of the sterilization unit 40 is not performed before the operation of the pump 25, sufficient sterilizing material remains in the water. can do.

Alternatively, when the control unit is connected to a power source, even if the user presses the power button to stop the operation of the evaporative cooler, the control unit operates according to an operation pattern in which the sterilization unit 40 repeats operation and stop at predetermined time intervals. The sterilization unit 40 can be controlled. That is, even if the user is not using the evaporative cooler, as long as the control unit is connected to the power source, the sterilization unit 40 that maintains the state continuously connected to the power source generates a sterilizing material at predetermined time intervals so that the sterilizing material is sufficiently prepared in advance. It can be maintained in the created state.

Alternatively, the controller may control the sterilization unit 40 to operate the sterilization unit 40 when an operation command of the sterilization unit 40 is input. That is, even if the sterilization unit 40 is operating according to a certain pattern, when the user manually inputs the sterilization operation, the sterilization unit 40 immediately operates to perform the control to generate the sterilization material. may be

variant

3 is a conceptual view of an evaporative cooler according to a modification of the present invention. Hereinafter, an evaporative cooler according to a modified example of the present invention will be described with reference to FIG. 3 . The evaporative cooler according to the modified example of the present invention is different from the evaporative cooler according to the first and second embodiments in the position where the sterilization unit 40 is provided and the basic control method of the sterilization unit 40 . The same or equivalent reference numerals are assigned to the same or equivalent components as the evaporative coolers according to Embodiments 1 and 2 of the present invention, and detailed descriptions thereof are omitted.

The sterilization unit 40 of the evaporative cooler according to a modification of the present invention may be provided outside the storage unit 30 . The sterilization unit 40 may include a sterilization tank 41 for accommodating water and a sterilization terminal 45 provided in the sterilization tank 41 . In addition, the sterilization unit 40 may generate sterilizing water containing a sterilizing material and mix it with the water supplied from the storage unit 30 to the air transport unit 20 .

The evaporative cooler according to the second embodiment of the present invention recovers the water stored in the storage unit 30 to the sterilization tank 41 to generate a sterilizing material, and then supplies it back to the storage unit 30, while a modification of the present invention The evaporative cooler according to the example supplies water to the sterilization tank 41, the sterilization terminal 45 generates a sterilizing material from the water stored in the sterilization tank 41, and the water stored in the sterilization tank 41 is sterilized water. After making it, the stored sterilizing water may be mixed with the water supplied from the storage unit 30 to the air transport unit 20 .

In FIG. 3 , the sterilization tank 41 is illustrated as being connected as a flow path for flowing water from the storage unit 30 to the air transport unit 20 , but the water stored in the sterilization tank 41 is transferred to the storage unit 30 . After being directly supplied, it may be supplied to the air transport unit 20 .

And when water is supplied to the sterilization tank 41, the control unit supplies power to the sterilization terminal 45 for a predetermined time to maintain the state in which the sterilization water is stored in the sterilization tank 41, and then the pump 25 operates and stores Before the water stored in the unit 30 is pumped to the air transport unit 20 , the pump 25 may be operated after the sterilizing water is supplied to the storage unit 30 from the sterilization unit 40 .

Alternatively, when water is supplied to the sterilization tank 41, the control unit supplies power to the sterilization terminal 45 for a predetermined time to maintain the state in which the sterilization water is stored in the sterilization tank 41, and then when the pump 25 operates The water stored in the storage unit 30 and the water stored in the sterilization tank 41 are pumped to the air-lift unit 20 to perform a control so that the sterilizing material sterilizes the bacteria contained in the water.

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

10: heat exchange unit
11: Inlet
19: outlet
20: airborne
25: pump
30: storage
40: sterilization unit
45: sterilization terminal

Claims (20)

a heat exchange unit having an inlet through which air is introduced and an outlet through which the air is discharged;
an air transport unit supplying water to the heat exchange unit so that the air introduced into the heat exchange unit through the inlet is cooled by the water supplied to the heat exchange unit and then discharged through the outlet;
a storage unit for storing water to be supplied from the air transport unit to the heat exchange unit;
a sterilization tank in which sterilization water is stored; and a sterilization terminal for generating a sterilizing material from the water stored in the sterilization tank so that the water stored in the sterilization tank becomes the sterilization water, and sterilizing bacteria contained in the water stored in the storage unit a sterilization unit for generating sterilization water containing the sterilization material from the water stored in the sterilization tank;
a pump for pressurizing the water stored in the storage unit to the air transport unit so that the water is supplied from the air transport unit;
a control unit for controlling the operation of the pump and the sterilizing unit;
a first flow path connecting the storage unit and the air transport unit, and in which the pump is disposed; and
and a second flow path connecting a portion located upstream of the pump among the first flow paths and the sterilization unit,
The control unit is:
When the control unit is connected to the power source and the power button for operating the evaporative cooler is selected, the control is performed so that the sterilization unit operates first before the operation of the pump,
Controls the sterilization unit so that the sterilization unit does not operate when the pump is operating,
When water is supplied to the sterilization tank, power is supplied to the sterilization terminal for a predetermined time to maintain the state in which the sterilization water is stored in the sterilization tank, and when the pump operates, the water stored in the storage unit is transferred to the first flow path. The sterilizing water stored in the sterilization tank is pumped to the airlifting unit through the first flow path through the second flow path, and the sterilizing material is supplied to the airlifting unit by pressure to sterilize bacteria contained in the water pumped to the airlifting unit. The evaporative cooler performs the control so that it does. The method according to claim 1,
The sterilizing unit is provided inside the storage unit, the evaporative cooler. The method according to claim 1,
The sterilization unit is provided outside the storage unit,
When the sterilization unit operates, the water stored in the storage unit is recovered to the sterilization unit and then supplied to the storage unit together with the sterilizing material generated in the sterilization unit. The method according to claim 1,
The sterilizing unit, in order to generate hypochlorous acid (HOCl) as the sterilizing material, oxidizes chlorine ions (Cl ⁻ ) in the water to chlorine (Cl ₂ ), an evaporative cooler. 5. The method according to claim 4,
The sterilization unit includes a sterilization terminal coated with a platinum group metal oxide that acts as a catalyst when the chlorine ions (Cl ⁻ ) are oxidized to the chlorine (Cl ₂ ). 6. The method of claim 5,
The control unit, the evaporative cooler for controlling the amount of the sterilizing material generated from the water by controlling the amount of power supplied to the sterilization terminal. 7. The method of claim 6,
The sterilization unit includes a plurality of the sterilization terminals spaced apart from each other by a predetermined interval,
The control unit, based on at least one of the amount of the water, TDS (total dissolved solids) of the water, the area in which the sterilization terminal is in contact with the water, the number of the sterilization terminals and the interval at which the sterilization terminals are spaced apart Evaporative cooler, which determines the amount of power to be supplied to the terminals. 8. The method of claim 7,
The control unit, when determining the amount of power to be supplied to the sterilization terminal based on the TDS of the water, if the TDS of the water is higher than the reference TDS, reduces the size of the power to be supplied to the sterilization terminal, and the TDS of the water is the standard An evaporative cooler, which increases the amount of power to be supplied to the sterilization terminal if it is lower than the TDS. The method according to claim 1,
The control unit controls the sterilization unit to repeat operation and stop at predetermined time intervals, the evaporative cooler. 10. The method of claim 9,
The sterilization unit includes a sterilization terminal that oxidizes chlorine ions (Cl ⁻ ) in the water to chlorine (Cl ₂ ) in order to generate hypochlorous acid (HOCl) as the sterilizing material, a plurality of which are provided to be spaced apart from each other by a predetermined interval,
The control unit controls the sterilization unit to repeat operation and stop of the sterilization unit by supplying or blocking power to the sterilization terminal,
The predetermined time and the operating time, which is the time to supply power to the sterilization terminal, are the amount of water, total dissolved solids (TDS) of the water, the area in which the sterilization terminal is in contact with the water, the number of the sterilization terminals and the sterilization terminal. is determined based on at least one of the spaced apart intervals. delete delete The method according to claim 1,
The control unit, the control unit is connected to a power source, when the selection of the power button for operating the evaporative cooler is released, the operation of the pump is stopped, but the sterilization unit performs control to operate according to a predetermined operation pattern , evaporative coolers. 14. The method of claim 13,
The control unit, when the control unit is connected to a power source, even if the selection of the power button for operating the evaporative cooler is released, the sterilization unit operates according to an operation pattern of repeating operation and stopping at predetermined time intervals. Controlling wealth, evaporative cooler. The method according to claim 1,
Wherein the control unit controls the sterilization unit to operate when an operation command of the sterilization unit is inputted, the evaporative cooler. The method according to claim 1,
The control unit further controls the amount of water stored in the storage unit,
The control unit, the evaporative cooler to perform a control so that the water stored in the storage unit to maintain a predetermined volume or more. 17. The method of claim 16,
The control unit determines the amount of water to be supplied to the storage unit based on the amount of water supplied from the storage unit to the air transport unit and the amount of water that is evaporated without being recovered to the storage unit after being supplied from the air transport unit to the heat exchange unit. Evaporative cooler. delete delete delete

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