KR102360455B1 - Electrolyzed water humidifier using ultrasonic - Google Patents

Abstract

The present invention relates to an ultrasonic humidifier, wherein the ultrasonic humidifier includes a body for accommodating raw water for generating humidification, an electrolysis module for electrolyzing raw water into electrolyzed water, and ultrasonic waves for generating spray particles with raw water or electrolyzed water using ultrasonic waves contains modules. For this reason, this ultrasonic humidifier can prevent scale generation and bacterial propagation by sterilizing and washing the water tank and spray path without going through a separate cleaning process. It works.

Description

Ultrasonic humidifier that sprays electrolyzed water

The present invention relates to an ultrasonic humidifier using electrolyzed water, and more particularly, by electrolyzing raw water to generate electrolyzed water, and spraying the generated electrolyzed water using ultrasonic waves, the water tank and spray path in which the electrolyzed water is accommodated are sterilized and cleaned by the electrolyzed water It relates to an ultrasonic humidifier that can prevent scale formation and bacterial growth.

A humidifier is an electric appliance that controls the humidity in the room by spraying or evaporating water to create water vapor.

Looking at the atomization method of these humidifiers, the nozzle atomization method of spraying water at high pressure from a narrow-diameter nozzle such as a sprayer and emitting fine water particles at high speed, natural wind or blowing air with a fan to the medium moistened with water. The humidifier can be classified into a natural evaporation (vaporization) spray method that evaporates, a heating spray method that boils water with electricity to release steam, and an ultrasonic spray method humidifier that vibrates water with ultrasonic waves to spray granulated water.

Among the spraying methods of such a humidifier, the ultrasonic atomizing method is the most commonly seen method in recent years due to the advantages of abundant atomization, quietness, and low energy consumption. However, in the ultrasonic spray method, since the water droplets in the liquid state are released together, various impurities contained in the water are also released into the air.

In order to solve the above problems, the water tank and the spray path of the humidifier should be frequently cleaned, but the conventional ultrasonic humidifier has a problem in that it is difficult to clean the corners due to the complicated structure. To improve this, an ultrasonic humidifier with an improved structure and easy cleaning has been released recently, but the recent ultrasonic humidifier with an improved structure also has the inconvenience of requiring frequent cleaning.

Republic of Korea Patent Registration No. 10-1660868 (2016.09.22)

The present invention is to solve the problems of the prior art mentioned above, and an object of the present invention is to prevent scale generation and bacterial propagation by sterilizing and washing the water tank and spray path with electrolyzed water without going through a separate washing process. It is to provide an ultrasonic humidifier with

Another object of the present invention is to provide an ultrasonic humidifier that allows the electrolytic module and the ultrasonic module to float below a certain depth from the water surface to smoothly generate the water contained in the water tank as electrolyzed water, and at the same time to enable the smooth generation of atomized particles. will provide

Another object of the present invention is to enable spraying after the received raw water is completely converted into electrolyzed water when the humidifier is turned on, and automatically determines the time until the raw water is converted into electrolyzed water according to the volume of the received raw water, and accordingly It is to provide an ultrasonic humidifier that can automatically adjust the spray timing.

Another object of the present invention is to provide an ultrasonic humidifier capable of easily replenishing raw water without directly moving the body of the humidifier.

An ultrasonic humidifier according to an embodiment of the present invention includes a body portion for accommodating raw water for generating humidification, an electrolysis module for electrolyzing raw water into electrolyzed water, and an ultrasonic module for generating spray particles with electrolyzed water using ultrasonic waves do.

At this time, the ultrasonic module is laminated coupled to the upper side of the electrolytic module, and the combination of the ultrasonic module and the electrolytic module may have its own buoyancy to float within a distance of a predetermined range from the water surface under the water surface of the raw water or electrolyzed water accommodated in the body portion.

In addition, in the ultrasonic module and the electrolytic module, one or more through-holes may be respectively formed so that the assembly penetrates in the vertical direction.

In addition, the ultrasonic module and the electrolytic module may have an inner space formed around the edge.

In addition, the ultrasonic humidifier further includes a wire portion having one end connected to the body portion and the other end connected to the assembly body, and the wire portion may be formed to be detachably detachable with one end or the other end by a magnetic body or the assembly body.

In addition, when a humidifying signal is generated, the ultrasonic humidifier may further include a controller for controlling the operation of the electrolysis module and operating the humidifying module after a delay time has elapsed.

In addition, the control unit may determine the delay time based on the volume of the raw water and the electrolyzed water accommodated in the body portion.

In addition, the ultrasonic humidifier further includes a water level sensor for measuring the level of raw water or electrolyzed water accommodated in the body, and the control unit includes an electrolysis control unit for operating the electrolysis module when a humidification signal is generated, and the water level detected by the water level sensor A volume determination unit for determining the volume of raw water accommodated in the body based on the information, a delay time determination unit for determining a delay time based on the determined volume, and a humidification module after the electrolysis module operates and the determined delay time elapses It may include a humidification control unit to control the operation.

In addition, the body portion has an opening formed at the upper side so that the generated spray particles are discharged to the outside, and a discharge pipe extending a predetermined length downward from the opening to form a guide path for the generated spray particles to the opening, and an opening. It is detachably coupled to the fart and includes a spray cap in which a spray port communicating with the opening is formed, and the discharge pipe may be formed to have a narrower cross-sectional area toward the lower end.

In addition, in the discharge pipe, the distance from the lower end to the inner bottom surface of the body part is formed to be close to a distance within the thickness length of the assembly, and one or more slits extending in the upper direction from the lower end are formed, and the assembly is the inner side of the discharge pipe can be placed in

According to the present invention, an electrolysis module for electrolyzing raw water with electrolyzed water is provided, so that the water tank and spray path are sterilized and washed by electrolyzed water without going through a separate washing process by spraying the electrolyzed water, thereby preventing scale generation and bacterial propagation, and air There are effects such as whitening, anti-aging, and moisturizing of the user's skin by electrolyzed water sprayed in the middle.

In addition, the ultrasonic module and the electrolytic module are not arranged in the water tank, but are arranged to float in the received raw water or electrolyzed water, so that the structure of the water tank can be simplified, and also the assembly in which the ultrasonic module and the electrolytic module are combined, and a wire for supplying power to the assembly It has the effect of being easy to wash because it is formed to be detachable.

In addition, there is an effect of enabling the smooth generation of spray particles by allowing the binder to float within a predetermined depth under the water surface by the buoyancy of the binder itself.

In addition, the electrolyzed water generated by the electrolysis module at the bottom of the assembly can be delivered to the vicinity of the ultrasonic module at the top of the assembly through a through hole formed for buoyancy control, so only a portion of the raw water accommodated in the humidifier is electrolyzed into electrolyzed water at the initial time point It also has the effect of allowing the electrolyzed water to be sprayed.

In addition, when a humidification signal is generated, the received raw water is converted into electrolyzed water and then sprayed, and the volume of the received raw water is measured through the floating height from the bottom of the assembly to automatically determine the time until the raw water is converted to electrolyzed water And by automatically adjusting the spraying time accordingly, the electrolyzed water can be sprayed even during the initial spraying, and there is an effect of preventing the delay time until the initial spraying from being excessively set compared to the received raw water.

In addition, the discharge pipe is formed in a shape in which the cross-sectional area is gradually narrowed in the direction of the lower end, and the spray cap at the top of the discharge pipe is formed to be detachable. There is an effect that can easily replenish raw water without moving it directly.

1 is a diagram schematically illustrating an ultrasonic humidifier according to an embodiment of the present invention.
2 is an exploded perspective view of an ultrasonic humidifier according to an embodiment of the present invention.
3 is a diagram illustrating a movement path of spray particles of an ultrasonic humidifier according to an embodiment of the present invention.
4 is a view showing an electrolysis module and an ultrasonic module of the ultrasonic humidifier according to an embodiment of the present invention.
5 is a diagram illustrating a cross-section of an electrolysis module and an ultrasonic module of an ultrasonic humidifier according to an embodiment of the present invention.
6 is a view showing a state in which the assembly of the ultrasonic humidifier according to an embodiment of the present invention is deviated from the center.
7 is a view showing a state in which the length of the discharge pipe of the ultrasonic humidifier is formed longer and the assembly is disposed inside the discharge pipe according to another embodiment of the present invention.
8 is a block diagram illustrating a water level sensor and a control unit of an ultrasonic humidifier according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, 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 describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

1 is a diagram schematically showing an ultrasonic humidifier according to an embodiment of the present invention, FIG. 2 is an exploded perspective view of the ultrasonic humidifier according to an embodiment of the present invention, and FIG. 3 is an embodiment of the present invention It is a diagram illustrating the movement path of the atomized particles of the ultrasonic humidifier, and FIG. 4 is a view showing the electrolysis module 20 and the ultrasonic module 30 of the ultrasonic humidifier according to an embodiment of the present invention. And Figure 5 is a view showing a cross-section of the electrolysis module 20 and the ultrasonic module 30 of the ultrasonic humidifier according to an embodiment of the present invention.

1 to 5 , the ultrasonic humidifier according to an embodiment of the present invention includes a body portion 10 for accommodating raw water for generating humidification, an electrolysis module 20 for electrolyzing raw water into electrolyzed water, and ultrasonic waves. It includes an ultrasonic module 30 for generating atomized particles using raw water or electrolyzed water. The ultrasonic humidifier according to the present invention electrolyzes the raw water contained in the body portion 10 with electrolyzed water to prevent scale generation and bacterial propagation by sterilizing and washing the water tank and spray path without going through a separate washing process. do.

That is, the ultrasonic humidifier according to this embodiment uses the electrode plate 21 provided in the electrolysis module 20 to electrolyze raw water accommodated in the body 10 into electrolyzed water, and the vibrator provided in the ultrasonic module 30 . By vibrating (31) to generate spray particles so that the electrolyzed water is sprayed, the inner space and the spray path of the body portion 10 in which the water is accommodated are sterilized and washed through the electrolyzed water.

At this time, the ultrasonic module 30 may be laminated and combined on the upper side of the electrolysis module 20 to manufacture a single assembly. By being formed to float under the water surface of the body portion 10, it is possible to simplify the structure of the internal space of the body portion 10, and through this, it is possible to facilitate cleaning of the interior of the body portion 10.

Here, in order to facilitate the generation of spray particles in the ultrasonic module 30 , the ultrasonic module 30 and the electrolysis module 20 are combined within a predetermined depth from the surface of the raw water or electrolyzed water accommodated in the body portion 10 . It can have its own buoyancy to float.

Specifically, the electrolytic module 20 and the ultrasonic module 30 is formed with a sealed inner space (S1, S2) around the edge to generate buoyancy. In addition, one or more first through-holes 22 penetrating in the vertical direction are formed in the electrolysis module 20 , and one or more second through-holes 32 penetrating in the vertical direction are formed in the ultrasonic module 30 . At this time, the first through hole 22 and the second through hole 32 communicate with each other so that the combination of the ultrasonic module 30 and the electrolytic module 20 penetrates in the vertical direction, thereby reducing the buoyancy of the assembly. Here, the buoyancy of the assembly is determined by the size of the internal spaces S1 and S2 and the weight of the assembly, and the number and size of the first and second through-holes 22 and 32 are adjusted to be proportional to the buoyancy of the assembly. Preferably, the number and size of the first and second through-holes 22 and 32 may be adjusted so that the distance l from the water surface to the vibrator 31 can be maintained at 1 to 4 cm.

In addition, the first and second through-holes 22 and 32 may serve as a passage through which the electrolyzed water generated by the electrolytic module 20 at the lower end of the assembly is circulated to the ultrasonic module 30 .

The electrolysis module 20 generates the raw water contained in the body portion 10 as electrolyzed water, and the ultrasonic module 30 uses the generated electrolyzed water to spray it, and the raw water located in the electrolysis module 20 starts to be generated as electrolyzed water. Thus, after a certain period of time has elapsed, the whole raw water contained in the body portion 10 is generated as electrolyzed water. Therefore, it takes a certain amount of time to generate the whole raw water contained in the body part 10 as electrolyzed water after the raw water is contained in the body part 10 . On the other hand, the electrolyzed water contained in the body portion 10 is changed to raw water when the humidifier is not used for a certain period of time.

The ultrasonic humidifier using electrolyzed water according to the present invention circulates and moves the electrolyzed water generated in the electrolysis module 20 directly to the ultrasonic module through the first and second through holes 22 and 32 to contain raw water in the body 10 . Electrolyzed water spraying is possible immediately after, or electrolyzed water spraying is possible even if it is not used for a certain period of time. Looking more specifically with reference to FIG. 5 , when the electrode plate 21 formed at the bottom of the assembly electrolyzes raw water to generate electrolyzed water, some of the generated electrolyzed water flows into the first through hole 22 formed around the electrode plate. do. And the electrolyzed water introduced into the first through-hole 22 is discharged to the upper side of the assembly through the second through-hole 32 communicating with the first through-hole 22 to the vicinity of the vibrator 31 disposed on the upper side of the assembly. It is supplied, and the electrolyzed water supplied to the vicinity of the vibrator 31 is granulated by the vibrator 31 and sprayed to the outside. As described above, in the ultrasonic humidifier according to this embodiment, the electrolyzed water generated from the electrode plate 21 circulates through a short path passing through the assembly to be supplied to the vibrator 31, so that raw water is contained in the body portion 10. Electrolyzed water spraying is possible immediately after, or electrolyzed water spraying is possible even if it is not used for a certain period of time.

On the other hand, the electrolysis module 20 and the ultrasonic module 30 are connected by the body portion 10 and the electric wire portion 40 for power supply. Specifically, the electric wire unit 40 has one end connected to the body unit 10 and the other end connected to at least one of the electrolytic module 20 and the ultrasonic module 30 to form the electrolytic module 20 or the ultrasonic module 30 . It can provide operating power. At this time, one end of the wire part 40 may be fastened to be detachably attached to the body part 10 , or the other end may be fastened to be detachably attached to the electrolytic module 20 or the ultrasonic module 30 . Here, the electrolytic module 20 and the ultrasonic module 30 are connected to each other with wires, and when power is supplied to one of the electrolytic module 20 or the ultrasonic module 30 through the wire part 40, through the connected wire The rest of the modules can also be powered.

Specifically, the electric wire part 40 may include a magnetic connection part 41 for connecting/separating using magnetism at one end or the other end. At this time, when the magnet connection part 41 is formed at one end or the other end of the electric wire part 40 , a magnet may be provided in the body part 10 connected thereto to correspond to the magnet connection part 41 . In addition, an airtight maintenance means such as an O-ring may be provided around the magnet connecting portion 41 to maintain airtightness during connection.

The body 10 consists of a lower end 11, an upper end 12 coupled to the upper side of the lower end, and a spray cap 13 coupled to the upper side of the upper end. An inner space is formed to accommodate it, and the upper end is formed open. The upper end 12 is coupled to the upper end of the lower end 11 and an opening 12a that is openly formed to discharge the spray particles to the outside is formed in the upper central portion, and the ultrasonic module 30 is disposed in the inner space of the lower end 11 . ) to form a guide path for guiding the spray particles generated in the opening (12a) from the opening (12a) to the lower end (11) direction is formed to extend a predetermined length discharge pipe (12b) is formed. And the spray cap 13 is detachably coupled to the opening 12a and a spray hole 13a communicating with the opening 12a is formed, and the spray hole 13a has an area smaller than the cross-sectional area of the guide path. do.

At this time, since the lower end 11, the upper end 12 and the spray cap 13 are each formed to be separable/combinable, the lower end 11 and the upper end 12 are separated to easily replenish the raw water into the lower end 11. Since the opening (12a) and the discharge pipe (12b) are formed through the opening (12a) even in a state in which only the spray cap (13) is separated and the lower part (11) and the upper part (12) are not separated separately ) through the lower part 11 can be replenished with raw water.

Preferably, the discharge pipe 12b is formed to have a narrower cross-sectional area from the opening 12a toward the lower end 11, so that raw water can be easily replenished through the opening 12a.

6 is a view showing a state in which the assembly of the ultrasonic humidifier according to an embodiment of the present invention is out of the center, and FIG. 7 is the length of the discharge pipe of the ultrasonic humidifier according to another embodiment of the present invention in one embodiment. It is formed longer than the length of the discharge pipe and is a view showing a state in which the assembly is disposed on the inside of the discharge pipe.

Referring to FIG. 6 , in the assembly of the ultrasonic humidifier according to an embodiment of the present invention, the assembly is out of the center due to tensile force due to the weight of the electric wire 40 , and is located close to the inner wall of the lower end 11 . may occur.

As such, when the assembly leaves the center, the spray particles generated by the vibrator 31 also leave the center and move upward, so they cannot directly flow into the discharge pipe 12b, and the inner wall of the lower end 11 and the upper end 12 and the discharge pipe ( After moving along the outer wall of 12b) may be introduced into the interior of the discharge pipe (12b). And when the spray particles move along the wall in this way, a significant amount of the spray particles form as dew on the wall during the movement process, and the amount of spray particles flowing into the discharge pipe 12b is significantly reduced, which is directly related to the reduction of the spray amount.

Therefore, referring to Figure 7, the discharge pipe (12b) according to another embodiment of the present invention may be formed longer than the discharge pipe according to an embodiment, preferably from the lower end of the discharge pipe (12b) the lower end (11) The distance (b) to the inner bottom surface of the assembly may be formed to be close to a distance within the thickness length (a) of the assembly. And at this time, the cross-sectional area of the discharge pipe (12b) may be formed to be wider than the cross-sectional area of the assembly so that the assembly is disposed inside the discharge pipe (12b).

That is, the assembly is arranged in a suspended state inside the discharge pipe 12b, whereby the spray particles generated from the vibrator 31 are generated inside the discharge pipe 12b, so the process itself of introducing the spray particles into the discharge pipe 12b is Since it is omitted, a loss in the amount of spray does not occur in the process in which the spray particles are introduced into the discharge pipe (12b).

At this time, one or more slits 12c extending upward from the lower end of the discharge pipe 12b are formed in the discharge pipe 12b, so that the raw water and electrolyzed water flow smoothly between the inside and the outside of the discharge pipe 12b. In addition, the electric wire part 40 may be disposed to pass through the slit 12c so as not to be caught in the discharge pipe 12b.

8 is a block diagram illustrating the water level sensor 50 and the controller 60 of the ultrasonic humidifier according to an embodiment of the present invention.

Referring to FIG. 8 , the ultrasonic humidifier according to this embodiment determines the time until the received raw water is converted into electrolyzed water, and the water level sensor 50 and the control unit 60 ) may be further included.

The electrolyzed water accommodated in the lower part 11 is converted back to raw water over time. In this way, if the electrolysis module 20 and the ultrasonic module 30 operate at the same time when the humidifier is not used for a predetermined time while the electrolyzed water is accommodated in the lower end 11, or when raw water is newly supplied to the lower end 11, the raw water is electrolyzed water. Since a predetermined time is required for conversion to , raw water is sprayed from the initial time point until a predetermined time elapses.

The ultrasonic humidifier according to this embodiment supplies power to the electrolyzed water generating button and the ultrasonic module 30 for generating electrolyzed water by supplying power to the electrolytic module 20 so that the electrolyzed water is sprayed from the time when the first spraying starts. A spray button to generate a spray can be formed separately. In this case, when it is determined that the electrolyzed water generation has progressed to some extent after the user inputs the electrolyzed water generation button, the user may input the spray button.

However, since such a process may cause inconvenience to the user, preferably, the ultrasonic humidifier according to the present embodiment performs spraying after electrolyzed water generation is performed only by inputting one power button to reduce the user's inconvenience. can

Specifically, the ultrasonic humidifier according to this embodiment can be driven in two modes. In the first mode, when the power button is input, power is supplied to the electrolysis module 20, and when a set time elapses, the ultrasonic module 30 is power can be supplied. The set time at this time may be a time until all raw water is regularly decomposed into electrolyzed water based on when the water is fully accommodated inside the lower part 11 .

In the second mode, when the power button is input, power is supplied to the electrolysis module 20, the volume of the received raw water is measured to determine the time until the raw water is converted into electrolyzed water, and after the determined time, the ultrasonic module 30 is By allowing power to be supplied, it is possible to ensure that the atomization occurs from the time of conversion to electrolyzed water. To this end, as described above, the water level sensor 50 and the control unit 60 may be provided.

Referring specifically to FIG. 8 , the controller 60 operates and controls the electrolysis module 20 when the power button is input, but does not immediately control the operation of the ultrasound module 30 . At this time, the water level sensor 50 detects the water level of the received raw water. Preferably, the water level sensor 50 is disposed on the inner wall surface of the upper end 12, and emits ultrasonic waves toward the surface of the received raw water to determine the water level. It may be an ultrasonic level sensor that detects it.

And the control unit 60 determines the delay time based on the distance information measured by the water level sensor 50, the electrolysis module 20 operates and when the delay time elapses, the ultrasonic module 30 is operated to control the spraying. let it start

More specifically, when the power button is input and a humidification signal is generated, the control unit 60 includes the electrolysis control unit 61 that controls the operation of the electrolysis module 20 and the water level information detected by the water level sensor 50 A volume determination unit 62 that calculates and determines the volume of raw water accommodated in the lower end 11 based on the volume determination unit 62, a delay time determination unit 63 that determines a delay time based on the determined volume, and the electrolysis module 20 It operates and may include a humidification control unit 64 that controls the operation of the ultrasound module 13 after the determined delay time has elapsed.

At this time, the volume determination unit 62 of the control unit calculates and determines the volume of the raw water accommodated in the lower end 11 based on the water level information sensed by the water level sensor 50 and the volume and shape of the inner space of the lower end 11, The delay time determining unit 63 determines the time required for the conversion by calculating the time taken for the conversion of raw water of the determined volume into electrolyzed water as a delay time, and the humidification control unit 64 determines after the electrolysis module 20 operates When the delay time elapses, by controlling the operation of the ultrasonic module 13, humidification using electrolyzed water can be performed from the initial point of spraying.

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. Accordingly, 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 scope equivalent thereto should be construed as being included in the scope of the present invention.

10: body part
11: lower part 12: upper part
12a: opening 12b: exhaust pipe
12c: slit
13: spray cap 13a: spray hole
20: electrolytic module
21: electrode plate 22: first through hole
30: ultrasonic module
31: vibrator 32: second through hole
40: wire part
41: magnetic connection
42: spring code
50: water level sensor
60: control unit
61: electrolysis control unit 62: volume determination unit
63: delay time determining unit 64: humidification control unit

Claims (10)

Body portion for accommodating raw water for humidification;
an electrolysis module for electrolyzing the raw water into electrolyzed water;
an ultrasonic module for generating spray particles in the electrolyzed water using ultrasonic waves; and
and a wire part having one end connected to the body part and the other end connected to the electrolysis module or the ultrasonic module,
The ultrasonic module is laminated on the upper side of the electrolysis module to form a single assembly, and the assembly has its own buoyancy to float within a predetermined depth from the surface of the raw water or electrolyzed water accommodated in the body portion,
the body part
an opening formed in the upper central portion so that the generated spray particles are discharged to the outside; and
Comprising a discharge pipe extending a predetermined length in the downward direction from the opening so that the generated spray particles form a guide path toward the opening,
The assembly is arranged to float in the interior of the discharge pipe, and the discharge pipe is close to a distance within the thickness length of the assembly from the lower end to the inner bottom surface of the body to prevent separation of the assembly disposed therein is formed,
The discharge pipe is formed with one or more slits extending a predetermined length in the upward direction from the lower end, and the electric wire part is disposed to pass through the slits.
delete The method of claim 1,
The ultrasonic module and the electrolytic module are ultrasonic humidifier, characterized in that one or more through-holes are respectively formed so that the assembly penetrates in the vertical direction.
The method of claim 1,
The ultrasonic module and the electrolytic module ultrasonic humidifier, characterized in that the inner space is formed around the edge.
The method of claim 1,
Ultrasonic humidifier, characterized in that one end or the other end of the electric wire part is detachably formed by magnetism with the body part or the assembly.
According to claim 1, wherein the ultrasonic humidifier
When a humidification signal is generated, the ultrasonic humidifier further comprises a control unit for controlling the operation of the electrolysis module and for controlling the operation of the humidification module after a delay time has elapsed.
7. The method of claim 6,
The control unit ultrasonic humidifier, characterized in that for determining the delay time based on the volume of the raw water and the electrolyzed water accommodated in the body portion.
The method of claim 7, wherein the ultrasonic humidifier
Further comprising a water level sensor for measuring the level of the raw water accommodated in the body portion,
the control unit
an electrolysis control unit for controlling the operation of the electrolysis module when a humidification signal is generated;
a volume determination unit for determining the volume of the raw water and the electrolyzed water accommodated in the body unit based on the water level information detected by the water level sensor;
a delay time determining unit for determining the delay time based on the determined volume; and
Ultrasonic humidifier, characterized in that it comprises a humidification control unit for controlling the operation of the humidification module after the electrolysis module operates and the determined delay time elapses.
According to claim 1, wherein the body portion
It further comprises a spray cap detachably coupled to the opening and formed with a spray port communicating with the opening,
The discharge pipe is an ultrasonic humidifier, characterized in that the cross-sectional area becomes narrower toward the lower end from the upper end.
delete

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