KR20210098046A - Humidifier and control method thereof - Google Patents

Abstract

A humidifier is disclosed. The humidifier comprises: a humidification member; a storage water tank located above the humidification member and accommodating water; a circulation water tank located under the humidification member and accommodating a certain amount of water; a circulation pump that supplies water from the circulation water tank to the humidification member; a valve selectively providing water from the storage water tank to the circulation water tank; and a drainage member selectively discharging water from the circulation water tank.

Description

Humidifier and its control method

The present disclosure relates to a humidifier and a method for controlling the same, and more particularly, to a humidifier capable of preventing contamination due to residual water remaining in the humidifier when the operation of the humidifier is terminated, and to a method for controlling the same.

A humidifier is a device for increasing or maintaining indoor humidity, and uses electricity to make water particles or water vapor and discharge it to the outside.

Types of humidifier include heating type that boils water by electricity and discharges it as steam, ultrasonic type that vibrates water with ultrasonic waves to make water droplets and discharges them, combined heating type and ultrasonic type, and natural evaporation by blowing wind through a humidifier wetted with water with a fan There are vaporization formulas that make

Even when the humidifier is not in use, water is always contained and the water stored in the humidifier is continuously circulated and used. there was

The present disclosure is in accordance with the above-mentioned necessity, and an object of the present disclosure is to provide a humidifier capable of preventing contamination due to residual water remaining in the humidifier when the operation of the humidifier is terminated, and a method for controlling the same.

A humidifier according to an embodiment of the present disclosure for achieving the above object is a humidifying member, located on the humidifying member, a storage bucket for accommodating water, a circulating bucket for accommodating a certain amount of water, a storage bucket for accommodating water, and a lower portion of the humidifying member , a circulation pump for supplying water from the circulation bucket to the humidifying member, a valve for selectively providing water from the storage bucket to the circulation bucket, and a drainage member for selectively discharging the water from the circulation bucket. .

In addition, the valve is a first three-way valve having a first inlet port connected to the storage bucket, a second inlet port receiving residual water removal pressure, and an outlet port connected to the circulation bucket, the first three-way valve is The first inlet port or the second inlet port may be selectively connected to the outlet port.

In addition, the circulation bucket may include a low water level sensor and a high water level sensor disposed above the low water level sensor.

In addition, when the low water level signal is received from the low water level sensor, the humidifier controls the valve so that the water in the storage bucket is provided to the circulation bucket, and when the high level signal is received from the high water level sensor, the water in the storage bucket is supplied It may further include a; processor for controlling the valve so as not to be.

In addition, the high water level sensor may detect a capacity of the circulating bucket except for a predetermined residual water capacity of the pipe from the full capacity of the circulating water tank.

In addition, it may further include a residual water bucket for accommodating the water discharged from the circulation bucket.

In addition, the drain member may include a drain pump, and an inlet of the drain pump may be connected to a lower portion or an upper portion of the circulation bucket.

In addition, the drain member may include a second three-way valve for selectively guiding the water contained in the circulation bucket to the circulation pump or the drain pump.

In addition, the drain member may include a drain valve, and an inlet of the drain valve may be connected to a lower portion of the circulation bucket.

In addition, the humidifier may further include a drain hole formed in the exterior, and the drain valve may selectively discharge the water accommodated in the circulation bucket to the drain hole.

In addition, the humidifier may further include a sterilizing device installed in the circulation bucket and sterilizing the water accommodated in the circulation bucket.

In addition, the humidifier may further include a supply pump and a water filter disposed on a supply pipe connecting the storage bucket and the circulation bucket.

In addition, the residual water container includes a residual water high level sensor, and when a signal is received from the residual water high level sensor, the humidifier may further include a processor to stop the operation of the humidifier and output a residual water container empty alarm to the outside. there is.

In addition, when an OFF signal is input, the humidifier may further include a processor for discharging the water accommodated in the circulation bucket to the residual water bucket by operating the drain member.

In addition, the control method of the humidifier in which the storage bucket, the humidifying member and the circulation bucket are sequentially located according to an embodiment of the present disclosure includes the steps of receiving a low water level signal for the circulation bucket, the water in the storage bucket to the circulation bucket Supplying water from the storage bucket to the circulation bucket using a selectively provided valve, receiving a high level signal for the circulation bucket, and controlling the valve so that water in the storage bucket is not supplied may include.

1 is a diagram conceptually illustrating a humidifier according to an embodiment of the present disclosure.
2 is a functional block diagram of a humidifier according to an embodiment of the present disclosure.
3 is a partial view showing a first three-way valve according to an embodiment of the present disclosure by enlarging A of FIG. 1 .
4 is a view illustrating an example of a drainage member according to an embodiment of the present disclosure.
5 to 7 are views illustrating another example of a drain member according to an embodiment of the present disclosure.
8 is a diagram illustrating an example of a circulation pump according to an embodiment of the present disclosure.
9 to 10 are views illustrating another example of a circulation pump according to an embodiment of the present disclosure.
11 is a partial view illustrating a drain kit disposed on a supply pipe according to an embodiment of the present disclosure.
12 is a flowchart illustrating a humidifier control method according to an embodiment of the present disclosure.

It should be understood that the embodiments described below are illustratively shown to help the understanding of the present disclosure, and the present disclosure may be implemented with various modifications, unlike the embodiments described herein. However, in the following description of the present disclosure, if it is determined that a detailed description of a related known function or component may unnecessarily obscure the subject matter of the present disclosure, the detailed description and specific illustration thereof will be omitted. In addition, the accompanying drawings are not drawn to scale in order to help understanding of the disclosure, but dimensions of some components may be exaggerated.

The terms used in this specification and claims have been chosen in consideration of the function of the present disclosure. However, these terms may vary depending on the intention, legal or technical interpretation of a person skilled in the art, and the emergence of new technology. Also, some terms are arbitrarily selected by the applicant. These terms may be interpreted in the meaning defined in the present specification, and if there is no specific term definition, it may be interpreted based on the general content of the present specification and common technical common sense in the art.

In the present specification, expressions such as “have,” “may have,” “include,” or “may include” indicate the presence of a corresponding characteristic (eg, a numerical value, function, operation, or component such as a part). and does not exclude the presence of additional features.

Terms such as first, second, etc. may be used to describe various elements, but the elements should not be limited by the terms. The above terms may be used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present disclosure, a first component may be referred to as a second component, and similarly, a second component may also be referred to as a first component.

In addition, terms such as 'front', 'rear', 'top', 'bottom', 'side', 'left', 'right', 'upper', 'bottom' used in the present disclosure are defined based on the drawings. and the shape and position of each component are not limited by this term.

In addition, since the present specification describes components necessary for the description of each embodiment of the present disclosure, the present disclosure is not necessarily limited thereto. Accordingly, some components may be changed or omitted, and other components may be added. In addition, they may be distributed and arranged in different independent devices.

Further, an embodiment of the present disclosure will be described in detail below with reference to the accompanying drawings and the contents described in the accompanying drawings, but the present disclosure is not limited or limited by the embodiments.

1 is a diagram conceptually illustrating a humidifier 10 according to an embodiment of the present disclosure. 2 is a functional block diagram of the humidifier 10 according to an embodiment of the present disclosure.

1 to 2, the humidifier 10 according to an embodiment of the present disclosure includes a housing 30, a storage bucket 100, a valve 200, a circulation bucket 300, a circulation pump 400, It may include a residual water container 500 , a drain member 600 , a humidification member 700 , and a processor 800 .

The humidifier 10 according to an embodiment of the present disclosure is a device for increasing or maintaining indoor humidity, and may be discharged to the outside by making water particles or water vapor using electricity, and the type is electricity water. It can be a heating type that boils water and discharges it as steam, an ultrasonic type that vibrates water with ultrasonic waves to create and discharges water droplets, a combined heating type and ultrasonic type combined type, and a vaporization type that naturally evaporates by blowing wind to a humidification element moistened with water with a fan. , but is not limited thereto.

The housing 30 forms the exterior of the humidifier 10 , and has a storage bucket 100 , a valve 200 , a circulation bucket 300 , a circulation pump 400 , a residual water bucket 500 , and a drain member 600 therein. ), the humidifying member 700, the processor 800 can be accommodated.

As shown in FIG. 1 , the housing 30 may have a substantially rectangular shape in cross section, and thus the exterior of the humidifier 10 may have a rectangular parallelepiped, cylindrical shape, etc., but is not limited thereto. .

The storage bucket 100 is positioned on the humidifying member 700 and may be formed to accommodate a predetermined amount of water. A supply pipe 120 capable of supplying water to the circulation bucket 300 may be connected to the storage bucket 100 .

As shown in FIG. 1 , the storage bucket 100 may be partially accommodated in the housing 30 , but is not limited thereto, and the whole may be accommodated in the housing 30 . The storage bucket 100 may be detachably installed in the humidifier 10, and when the storage bucket 100 needs to be filled with water, the user separates the storage bucket 100 from the humidifier 10 and stores the storage bucket 100. It can be re-mounted to the humidifier 10 after filling the water.

The supply pipe 120 may be connected to the lower portion of the storage container 100 . A supply port 110 may be provided at a lower portion of the storage bucket 100 to connect the supply pipe 120 .

For example, the supply port 110 may be installed at a height of about 1/10 of the height of the storage bucket 100 from the bottom of the storage bucket 100 . When the supply port 110 is installed in this way, approximately 90% of the water stored in the storage bucket 100 can be used.

Various types of water level sensors 130 may be installed in the storage bucket 100 . For example, a water level sensor 130 capable of continuously detecting the level of water remaining in the storage bucket 100 may be installed.

As another example, the storage bucket 100 may be provided with a water level sensor 130 capable of detecting that the water accommodated in the storage bucket 100 reaches a preset low water level. The water level sensor 130 may output a low water level signal to the processor 800 when the water level stored in the storage bucket 100 reaches a preset low water level.

When the low water level signal output by the water level sensor 130 is input to the processor 800 , the operation of the humidifier 10 may be stopped, and a water tank replenishment alarm may be output through the display 810 or the alarm 820 .

The valve 200 is located on the supply pipe 120 , and may selectively provide water from the storage bucket 100 to the circulation bucket 300 . Specifically, when the low water level signal is received from the circulation low water level sensor 350 , the processor 800 opens the supply pipe 120 to provide the water from the storage bucket 100 to the circulation bucket 300 . can be controlled

On the other hand, when the high level signal is received from the circulation high level sensor 350 , the processor 800 closes the supply pipe 120 to close the valve 200 so that the water in the storage bucket 100 is not provided to the circulation bucket 300 . can be controlled

The circulation bucket 300 is disposed at the lower end of the storage bucket 100 , and may receive water from the storage bucket 100 through the supply pipe 120 . Since the circulation bucket 300 is disposed at the lower end of the storage bucket 100 , water can be supplied from the storage bucket 100 by gravity without an additional power device such as a pump.

In addition, the circulation bucket 300 can receive a predetermined amount of water from the storage bucket 100 to accommodate the water supplied to the humidifying member 700 , and is formed so as to recover the water discharged from the humidifying member 700 . can be

The circulation bucket 300 is located under the humidification member 700 , and may receive water from the storage bucket 100 located above the humidification member 700 without separate power. Accordingly, since it is not necessary to provide an additional power device such as a pump to move the water from the storage bucket 100 to the circulation bucket 300 , the manufacturing cost and power consumption of the humidifier 10 can be reduced.

In addition, the circulation bucket 300 may be formed to discharge the accommodated water to the residual water bucket 500 . And, the circulation bucket 300 may be formed to have a smaller capacity than the storage bucket (100). For example, the capacity of the circulation bucket 300 may be set to 10 to 30% of the capacity of the storage bucket 100, but is not limited thereto.

The circulation bucket 300 may be formed in a sealed form, and a humidification port 310 for supplying water to the humidification member 700, a recovery port 320 through which water discharged from the humidification member 700 flows in, storage It may include an inlet port 330 through which water supplied from the bucket 100 is introduced, and a drain port 340 for discharging water to the residual water bucket 500 .

In addition, although not shown, the circulation bucket 300 may be provided with an opening in the upper or lower portion to be able to clean the inside, a removable lid may be installed in the opening.

A circulation pump 400 for supplying water to the humidification member 700 may be installed in the humidification port 310 . Accordingly, when the circulation pump 400 operates, the water in the circulation bucket 300 may be supplied to the humidifying member 700 .

One end of the supply pipe 120 may be connected to the inlet port 330 . Accordingly, when the valve 200 opens the supply pipe 120 , the water of the storage bucket 100 may be supplied to the circulation bucket 300 through the supply pipe 120 .

When a certain amount of water accommodated in the circulation bucket 300 is consumed, the circulation bucket 300 may include a circulating low water level sensor 350 to receive water from the storage bucket 100 . The circulation low water level sensor 350 may output a low water level signal to the processor 800 when the water level of the circulation bucket 300 reaches the reference low water level.

When the low water level signal is output from the circulation low water level sensor 350 installed in the circulation bucket 300, the processor 800 operates the drain member 600 to discharge the remaining water in the circulation bucket 300 to the residual water bucket 500 and , by controlling the valve 200 to supply a certain amount of water from the storage bucket 100 to the circulation bucket 300 .

The circulation low water level sensor 350 may be formed to output a low water level signal when the water in the circulation bucket 300 remains 5-25% of the capacity of the circulation bucket 300 . The low water level of the water at which the circulation low water level sensor 350 outputs the low water level signal may vary depending on the state of water and the humidification operation condition.

The circulation bucket 300 may include a circulation high level sensor 360 to limit the amount of water supplied from the storage bucket 100 . The circulation high level sensor 360 may output a high level signal to the processor 800 when the water level of the circulation bucket 300 reaches the reference high level.

When the high level signal is output from the circulation high level sensor 360 , the processor 800 may control the valve 200 to block the supply of water from the storage bucket 100 to the circulation bucket 300 .

In addition, when the high level signal is output from the circulation high level sensor 360 , the processor 800 recognizes that the circulation bucket 300 is full. Accordingly, if necessary, the processor 800 may operate the circulation pump 400 to supply water to the humidifying member 700 .

Specifically, the circulation high level sensor 360 is a preset pipe residual water capacity in the full water capacity of the circulation bucket 300 (eg, the capacity of the supply pipe 120 located between the valve 200 and the circulation bucket 300) It is possible to output a high level signal by sensing the capacity except for .

That is, after the high level signal of the circulation high level sensor 360 is output, even if the residual water on the supply pipe 120 that has already passed through the valve 200 is supplied to the circulation bucket 300 , the water in the circulation bucket 300 . This may not overflow to the outside.

A sterilizing device 370 may be installed in the circulation bucket 300 to remove bacteria in the water accommodated in the circulation bucket 300 to prevent the water in the circulation bucket 300 from being contaminated.

For example, the sterilization device 370 may include an electrolysis device. The electrolysis device may electrolyze the water contained in the circulation bucket 300 to remove bacteria in the water.

Meanwhile, the processor 800 may determine whether the water contained in the circulation bucket 300 is contaminated by using the sterilization device 370 . For example, the processor 800 may monitor a current generated when the electrolysis device electrolyzes water, and if the current is equal to or greater than a reference value, it may be determined that the water is contaminated. When it is determined that the water is contaminated, the processor 800 may stop the operation of the humidifier 10 and output a water pollution alarm through the display 810 or the alarm 820 .

When the sterilization is finished, the processor 800 may operate the circulation pump 400 to supply water from the circulation bucket 300 to the humidification member 700 .

The circulation pump 400 is provided in the humidification pipe 410 to suck the water of the circulation bucket 300 and supply it to the humidification member 700 . For example, the inlet of the circulation pump 400 is

It is connected to the humidification port 310 of the circulation bucket 300 , and the outlet of the circulation pump 400 may be connected to the humidification pipe 410 . Accordingly, when the circulation pump 400 operates, the water of the circulation bucket 300 may be supplied to the humidification member 700 through the humidification pipe 410 .

The residual water bucket 500 may accommodate the water discharged from the circulation bucket 300 , and may be connected to the circulation bucket 300 through a drain pipe 630 . The drain port 340 of the circulation bucket 300 may be connected to one end of the drain pipe 630 .

A residual water high level sensor 510 may be installed in the residual water container 500 . The residual water high level sensor 510 may output a high water level signal when the water level collected in the residual water container 500 reaches a reference high level.

When the high water level signal is output from the residual water high level sensor 510, the processor 800 stops the operation of the humidifier 10, and outputs a residual water tank empty alarm to the outside through the display 810 or the alarm 820. . The user may separate the residual water container 500 from the humidifier 10 , discard the water in the residual water container 500 , and then mount the empty residual water container 500 to the humidifier 10 again.

Meanwhile, a drain member 600 may be installed between the circulation bucket 300 and the residual water bucket 500 so that the water of the circulation bucket 300 can be selectively discharged to the residual water bucket 500 .

The drain member 600 may be installed in the drain pipe 630 , and a drain pump 610 or a drain valve 620 may be used. Various embodiments of the drain member 600 will be described later with reference to FIGS. 4 to 7 .

The humidifying member 700 may vaporize the water supplied from the circulation bucket 300, and includes a distributor 710, a humidifying element 750, a humidifying element case 760, and a recovery unit 770. can do.

The distributor 710 may distribute the water supplied from the circulation bucket 300 to the humidifying element 750 . The distributor 710 may be formed in a tube shape, and a plurality of nozzles 720 may be provided on the lower surface of the distributor 71 in which the humidifying element 75 is installed.

The plurality of nozzles 720 may each have an inner diameter of 0.5 to 3 mm, and may be formed such that the sum of the total cross-sectional areas of the nozzles 720 is smaller than the cross-sectional area of the flow path portion of the distributor 710 . The distributor 710 may be formed to be sealed except for the plurality of nozzles 720 .

The distributor 710 receives a predetermined amount of water supplied by the circulation pump 400 , and a portion of the received water may be supplied to the humidifying element 750 through a plurality of nozzles 720 . At this time, water may be supplied to the humidifying element 750 through the plurality of nozzles 720 by gravity.

The plurality of nozzles 720 are in an open state, and the amount of water supplied to the distributor 710 by the circulation pump 400 is the amount of water discharged from the distributor 71 to the humidification element 750 through the plurality of nozzles 720 . It can be set to be more than the amount.

A humidification water level sensor 740 may be installed so as to detect the level of water accommodated in the distributor 710 . The processor 800 may supply or block water to the distributor 710 by controlling the circulation pump 400 according to a signal output from the humidification water level sensor 740 .

The humidifying element 750 is a kind of filter for vaporizing water, and may be formed of a humidifying cloth. The humidifying element 750 is installed under the distributor 710 and may be wetted by water discharged from the plurality of nozzles 720 .

A fan 730 may be installed behind the humidifying element 750 . Accordingly, when the fan 730 operates, the wind generated by the fan 730 may pass through the humidifying element 750 , and the water wetted by the humidifying element 750 is vaporized and discharged to the outside of the humidifier 10 . can be

The humidifying element 750 may be detachably installed in the humidifying element case 760 installed in the housing 30 of the humidifier 10 . Accordingly, the user can freely replace the humidifying element 750 .

A recovery unit 770 may be provided at a lower end of the humidifying element 750 . The recovery unit 770 may collect water that is not completely vaporized while passing through the humidifying element 750 . A hole 780 may be provided at the bottom of the recovery unit 770 to discharge the collected water. To this end, the bottom surface of the recovery unit 770 may be inclined toward the hole 780 .

Since the recovery unit 770 is connected to the circulation bucket 300 , the water collected in the recovery unit 770 may be discharged to the circulation bucket 300 and reused. Specifically, the hole 780 of the recovery unit 770 may be connected to the recovery port 320 of the circulation bucket 300 by a recovery pipe 790 . Accordingly, the water collected in the recovery unit 770 may be discharged to the passage circulation bucket 300 through the hole 780 , the recovery pipe 790 , and the recovery port 320 .

The water collected into the circulation bucket 300 through the recovery port 320 may be mixed with the water accommodated in the circulation bucket 300 , and may be supplied to the humidification member 700 by the circulation pump 400 again.

The humidifier 10 may include a display 810 and an alarm 820 . The display 810 may output status information of the humidifier 10 under the control of the processor 800, for example, information such as the water level of the storage bucket 100, or an alarm regarding the various humidifiers 10 described above. can be formed.

For example, the display 810 may be formed of a liquid crystal panel. The alarm 820 is provided to output the various alarms described above in sound under the control of the processor 800 , and may include a speaker, a buzzer, and the like.

The processor 800 may include, for example, a processing circuit such as an electronic circuit board, and various electronic components and/or program modules such as an ASIC, ROM, RAM, and the like. The processor 800 is installed in the housing 30 of the humidifier 10 , and may be installed in a control panel (not shown) provided so that a user can control the humidifier 10 .

Hereinafter, a method for the processor 800 to control the above-described components of the humidifier 10 will be described in detail.

When the humidifier 10 is turned on, the processor 800 may control the valve 200 to supply water from the storage bucket 100 to the circulation bucket 300 .

When the water supplied to the circulation bucket 300 reaches a predetermined water level, the circulation high level sensor 360 may output a high level signal. The processor 800 may receive the output high level signal, and may control the valve 200 so that the water of the storage bucket 100 is not supplied to the circulation bucket 300 .

The processor 800 may operate the sterilization device 370 disposed in the circulation bucket 300 to sterilize the water accommodated in the circulation bucket 300 . When the sterilization of the sterilization device 370 is finished, the processor may operate the circulation pump 400 to supply water from the circulation bucket 300 to the humidification member 700 .

Thereafter, the processor 800 may operate the fan 730 to allow wind generated by the fan 730 to pass through the humidifying element 750 . Accordingly, water in the humidifier 750 may be vaporized and discharged to the outside of the humidifier 10 .

The processor 800 may continue to operate the circulation pump 400 so that the water in the circulation bucket 300 circulates through the humidifying member 700 . While the water in the circulation bucket 300 circulates through the humidifying member 700 , since the water is vaporized in the humidifying element 750 , the water in the circulation bucket 300 may be reduced.

When the water in the circulation bucket 300 reaches the low water level, the circulation low water level sensor 350 may output a low water level signal. When the low water level signal is input from the circulation low water level sensor 350, the processor 800 turns off the circulation pump 400 to control the water in the circulation bucket 300 not to be supplied to the humidifying member 700. there is.

At the same time, the processor 800 may control the valve 200 so that the water of the storage bucket 100 is supplied to the circulation bucket 300 again. While the humidifier is on, the above-described control process of the processor 800 may be repeated.

When the humidifier 10 is turned off, the processor 800 may control the drain member 600 to discharge the water from the circulation bucket 300 to the residual water bucket 500 .

For example, when the drain member 600 is the drain pump 610 , the processor 800 is configured to discharge the water remaining in the circulation container 300 to the residual water container 500 through the drain pipe 630 ( 610) can be activated.

As another example, when the drain member 600 is the drain valve 620 , the processor 800 may open the drain valve 620 . Accordingly, the water remaining in the circulation bucket 300 may be discharged to the residual water bucket 500 through the drain pipe 630 and the drain valve 620 by gravity.

When the water in the residual water bucket 500 reaches a high water level, the residual water high level sensor 510 may output a high water level signal. When a high level signal is input from the residual water high level sensor 510, the processor 800 stops the operation of the humidifier 10, and outputs a residual water container empty alarm to the outside through the display 810 or the alarm 820. .

As described above, in the humidifier 10 according to an embodiment of the present disclosure, since the water accommodated in the circulation bucket 300 is continuously sterilized by the sterilizer 370, clean water can always be supplied to the humidifying member 700. there is.

In addition, since the water remaining after circulating the humidifying member 700 is discharged to the residual water bucket 500 without mixing with the water newly supplied from the storage bucket 100, the humidifying member 700 or the circulation bucket 300 by the residual water. This contamination can be prevented.

3 is a partial view showing a first three-way valve according to an embodiment of the present disclosure by enlarging A of FIG. 1 . Referring to FIG. 3 , the valve disposed on the supply pipe 120 to selectively provide water from the storage bucket to the circulation bucket 300 may be the first three-way valve 210 having three ports.

Specifically, the first three-way valve 210 is a first inlet port 221 connected to the storage tank through the first supply pipe 121 , and a second receiving pressure for removing residual water through the second supply pipe 122 . It may have an outlet port 213 connected to the circulation bucket 300 through the inlet port 212 and the third supply pipe 123 .

The first three-way valve 210 may selectively connect the first inlet port 211 or the second inlet port 330 to the outlet port 213 . That is, when the low water level signal is received from the circulation low water level sensor 350 , the processor 800 performs the first inlet port 211 and the outflow of the first three-way valve 210 so that the water of the storage bucket is provided to the circulation bucket 300 . The port 213 may be controlled to be connected.

In addition, when a high water level signal is received from the circulation high level sensor 360, the processor 800 is configured to prevent the water of the storage bucket 100 from being provided to the circulation bucket 300 so that the second inlet port of the first three-way valve 210 ( 330) and the outflow port 213 may be controlled to be connected.

In particular, the first three-way valve 210 may receive residual water removal pressure through the second inlet port 330 connected to the second supply pipe 122 with one open side. Accordingly, when the second inlet port 330 and the outlet port 213 are connected, the residual water remaining in the third supply pipe 123 may be moved to the circulation bucket 300 by external pressure.

Although it is shown that the open side of the second supply pipe 122 is extended to the outside of the humidifier 10 , it is also possible to be located inside the humidifier 10 , and the remaining water is discharged through the second inlet port 330 . It is sufficient if it is formed so that a repulsive pressure is transmitted.

By the above-described configuration and arrangement of the first three-way valve 210, the residual water remaining between the storage bucket 100 and the circulation bucket 300 is deleted, so that contamination of the inside of the humidifier 10 by the residual water can be prevented there is.

4 is a diagram illustrating an example of a drain member 600 according to an embodiment of the present disclosure. 5 to 7 are views illustrating another example of the drain member 600 according to an embodiment of the present disclosure.

Referring to FIG. 4 , the drain member 600 is installed in the drain pipe 630 connecting the circulation bucket 300 and the residual water bucket 500 , and a drain pump 610 may be used as the drain member 600 . .

One end of the drain pump 610 may be connected to the lower surface of the circulation bucket 300 . That is, the drain port 340 of the circulation bucket 300 is installed on the lower surface of the circulation bucket 300 , and a drain pipe 630 connected to the inlet of the drain pump 610 in the drain port 340 can be installed. there is. The outlet of the drain pump 610 may be connected to the upper part of the residual water container 500 through the drain pipe 630 .

Accordingly, when the drain pump 610 operates, the water in the circulation bucket 300 may be discharged to the residual water bucket 500 through the first drain pipe 630a, and when the drain pump 610 does not operate, the circulation The water in the bucket 300 may not be discharged to the residual water bucket 500 .

In FIG. 5 , the drain pump 610 is connected to the lower surface of the circulation bucket 300 , but the drain pump 610 may be connected to the upper part of the circulation bucket 300 as shown in FIG. 9 .

Referring to FIG. 5 , one end of the drain pump 610 may be connected to the upper surface of the circulation bucket 300 . Specifically, a drain port 340 is provided on the upper surface of the circulation bucket 300 , and the drain pipe 630 may be installed to be inserted into the drain port 340 . The first drain pipe 630a may be installed so that one end of the first drain pipe 630a is adjacent to the bottom surface of the circulation bucket 300 .

That is, when the drain pump 610 operates, the first drain pipe 630 is installed so that all the water contained in the circulation bucket 300 can be discharged to the residual water bucket 500 through the first drain pipe 630a. . The outlet of the drain pump 610 may be connected to the upper part of the residual water container 500 through the second drain pipe 630b.

Accordingly, when the drain pump 610 operates, the water in the circulation bucket 300 may be discharged to the residual water bucket 500 through the drain pipes 630a and 630b, and when the drain pump 610 does not operate, circulation The water in the bucket 300 may not be discharged to the residual water bucket 500 .

In FIGS. 4 and 5 , the case where the drain pump 610 is used as the drain member 600 has been described, but the drain valve 620 may be used as the drain member 600 .

Referring to FIG. 6 , the drain valve 620 may be installed in the drain pipe 630 connecting the circulation bucket 300 and the residual water bucket 500 .

One end of the drain valve 620 may be connected to the lower surface of the circulation bucket 300 . That is, the drain port 340 of the circulation bucket 300 is installed on the lower surface of the circulation bucket 300 , and the first drain pipe 630 connected to the inlet of the drain valve 620 in the drain port 340 is installed. can be

The outlet of the drain valve 620 may be connected to the residual water container 500 through the second drain pipe 630b. The second drain pipe 630b may be connected to the inlet port 520 provided at the upper portion of the residual water container 500 .

At this time, the circulation bucket 300 may be installed on the upper side of the residual water bucket 500 so that the water of the circulation bucket 300 is discharged to the residual water bucket 500 by gravity.

When the drain valve 620 is installed as shown in FIG. 6 , when the drain valve 620 is opened by the processor 800 , the water in the circulation bucket 300 flows through the first and second drain pipes 630a and 630b. ) may be discharged to the residual water bucket 500 through, and when the drain valve 620 is closed, the water in the circulation bucket 300 may not be discharged to the residual water bucket 500 .

Referring to FIG. 7 , in the humidifier 10 according to an embodiment of the present disclosure, a drain valve 620 may be used as a drain member 600 , and a residual water container 500 to discharge water from the circulation container 300 . ) instead, a drain hole 31 may be formed in the housing 30 .

Specifically, one end of the drain valve 620 may be connected to the drain port 340 installed on the wave front of the circulation bucket 300 through the first drain pipe 630a. The other end of the drain valve 620 may be connected to the drain hole 31 through the second drain pipe 630b.

The circulation bucket 300 may be installed above the drain hole 31 so that the water of the circulation bucket 300 is discharged to the drain hole 31 by gravity.

When the drain valve 620 is installed as shown in FIG. 7 , when the drain valve 620 is opened by the processor 800 , the water in the circulation bucket 300 flows through the first and second drain pipes 630a and 630b. ) may be discharged to the outside of the humidifier through the drain hole 31, and when the drain valve 620 is closed, the water in the circulation bucket 300 may not be discharged to the outside of the humidifier.

Accordingly, since it is not necessary to separately provide a residual water container, it is possible to reduce manufacturing cost and reduce the size of the humidifier. In addition, since the water discharged from the circulation bucket 300 can be immediately discharged to the outside of the humidifier through the drain hole 31, it is possible to create a cleaner internal environment of the humidifier.

8 is a diagram illustrating an example of a circulation pump 400 according to an embodiment of the present disclosure. 9 to 10 are views showing another example of the circulation pump 400 according to an embodiment of the present disclosure.

8 to 9 , the circulation pump 400 may be located inside or outside the circulation bucket 300 so that one end of the circulation pump 400 may be connected to the upper surface of the circulation bucket 300 .

When the circulation pump 400 is located inside the circulation bucket 300, water can move directly from the circulation bucket 300 to the circulation pump 400 without passing through the pipe, so the arrangement and shape of the humidification pipe can be simplified. can be formed, and miniaturization of the humidifier can be made possible.

Specifically, a humidification port 310 is provided on the upper surface of the circulation bucket 300 , and the first humidification pipe 61a may be installed to be inserted into the humidification port 310 . The first humidification pipe (410a) may be installed so that one end of the first humidification pipe (410a) is adjacent to the bottom surface of the circulation bucket (300).

That is, when the circulation pump 400 operates, the first humidification pipe 410a can be installed so that all the water accommodated in the circulation bucket 300 can be provided to the humidification member 700 through the first humidification pipe 61a. there is.

The outlet of the circulation pump 400 may be connected to the humidifying member through the second humidifying pipe 410b.

Therefore, when the circulation pump 400 operates, the water in the circulation bucket 300 may be provided to the humidification member 700 through the humidification pipes 410a and 410b, and if the circulation pump 400 does not operate, circulation Water in the bucket 300 may not be provided to the humidifying member 700 .

Referring to FIG. 10 , the drain member 600 may include a circulation pump 400 and a second three-way valve 220 having three ports at the lower side of the circulation bucket 300 .

The second three-way valve 220 is connected to the circulation pump 400 through the third inlet port 221 and the first humidification pipe 410a connected to the humidification port 310 installed on the lower side of the circulation bucket 300 . It may have a third outlet port 223 connected to the drain pump 610 through the second outlet port 222 and the first drain pipe 630a.

The second three-way valve 220 may have each port connected to the circulation bucket 300, the circulation pump 400 and the drain pump 610, respectively, and drain the water contained in the circulation bucket 300 to the circulation pump 400 or drain. A pump 610 may be optionally guided.

Specifically, when the sterilization end signal is received from the sterilization device 370, the processor 800 is configured to provide a third inlet port ( 221) and the second outlet port 222 may be controlled to be connected.

In addition, when the humidification end signal is received, the processor 800 controls the third inlet port 221 and the third outlet port of the second three-way valve 220 so that the water of the circulation bucket 300 is provided to the drain pump 610 . 223 can be controlled to be connected.

That is, since the humidification port 310 of the circulation bucket 300 may also serve as the above-described drain port 340 , a separate drain port 340 may not be provided. Accordingly, the number of ports and pipes of the circulation bucket 300 is reduced, and the arrangement of the pipes and the manufacturing process of the circulation bucket 300 can be simplified.

11 is a partial view showing the cleaning kit 900 disposed on the supply pipe 120 according to an embodiment of the present disclosure. Referring to FIG. 11 , a cleaning kit 900 including a supply pump 910 and a water filter 920 may be installed on the supply pipe 120 connecting the storage bucket 100 and the circulation bucket 300 . there is.

The water filter 920 may filter the water supplied from the storage bucket 100 and supply the filtered water to the circulation bucket 300 . The water filter 920 may remove sludge, bacteria, and the like in water.

For example, the water filter 920 may be formed of an ultra filtration membrane filter, but is not limited thereto, and an ultra filtration membrane filter, a sediment filter, and an activated carbon filter are sequentially formed. It may be formed of a filter connected by

12 is a flowchart illustrating a method for controlling the humidifier 10 according to an embodiment of the present disclosure. 12, the control method of the humidifier 10 in which the storage bucket 100, the humidification member 700 and the circulation bucket 300 are sequentially located is the step of receiving a low water level signal for the circulation bucket 300 ( S610), using the valve 200 for selectively providing the water of the storage bucket 100 to the circulation bucket 300, supplying the water of the storage bucket 100 to the circulation bucket 300 (S620) , Receiving a high level signal for the circulation bucket 300 (S630) and may include the step of controlling the valve so that the water of the storage bucket is not supplied (S640).

Specifically, when the low water level signal for the circulation bucket 300 is received, the processor 800 controls the valve 200 to supply the water of the storage bucket to the circulation bucket 300, and when the high water level signal is received, the storage bucket The valve 200 may be controlled so that the water of 100 is not supplied to the circulation bucket 300 .

According to the control method of the humidifier 10 described above, a certain amount or more of water can always be accommodated in the circulation bucket 300 , and accordingly, a constant flow rate can be supplied from the circulation bucket 300 to the humidification member 700 .

Therefore, it is possible to prevent the partial drying of a part of the humidifying member 700, and the humidifying member 700 supplied with a constant flow rate can be uniformly vaporized throughout the humidifying member 700, so that the humidifier 10 ), the optimal efficiency can be sustained.

In the above, preferred embodiments of the present disclosure have been illustrated and described, but the present disclosure is not limited to the specific exemplary embodiments described above, and it is common in the technical field to which the disclosure pertains without departing from the gist of the present disclosure as claimed in the claims. Various modifications may be made by those having the knowledge of

10: humidifier 30: housing
100: storage bucket 200: valve
300: circulation bucket 400: circulation pump
500: residual water tank 600: no drainage
700: absence of humidification 800: processor
900: clean kit

Claims (15)

in the humidifier,
lack of humidification;
a storage bucket located on the humidifying member and accommodating water;
a circulation bucket located under the humidifying member and accommodating a predetermined amount of water;
a circulation pump for supplying water from the circulation bucket to the humidifying member;
a valve for selectively providing water from the storage bucket to the circulation bucket; and
A humidifier comprising a; a drainage member for selectively discharging the water of the circulation bucket. According to claim 1,
The valve is
A first three-way valve having a first inlet port connected to the storage bucket, a second inlet port receiving residual water removal pressure, and an outlet port connected to the circulation bucket,
The first three-way valve selectively connects the first inlet port or the second inlet port to the outlet port. According to claim 1,
The circulating bucket includes a low water level sensor and a high water level sensor disposed above the low water level sensor. 4. The method of claim 3,
When the low water level signal is received from the low water level sensor, the valve is controlled so that the water in the storage bucket is provided to the circulation bucket, and when the high level signal is received from the high level sensor, the valve is closed so that the water in the storage bucket is not provided. A humidifier further comprising a; processor to control. 4. The method of claim 3,
The high water level sensor is
A humidifier that detects a capacity excluding a preset remaining pipe residual water capacity from the full water capacity of the circulating water tank. According to claim 1,
A humidifier further comprising a residual water bucket accommodating the water discharged from the circulation bucket. According to claim 1,
The drain member comprises a drain pump,
The inlet of the drain pump is connected to a lower portion or an upper portion of the circulation water tank. 8. The method of claim 7,
The drain member includes a second three-way valve for selectively guiding the water contained in the circulation bucket to the circulation pump or the drain pump. According to claim 1,
the drain member comprises a drain valve;
The inlet of the drain valve is connected to the lower part of the circulation water tank. 10. The method of claim 9,
Further comprising; a drain hole formed in the exterior of the humidifier,
The drain valve selectively discharges the water contained in the circulation bucket to the drain hole. According to claim 1,
The humidifier further comprising; a sterilizing device installed in the circulation bucket and sterilizing the water accommodated in the circulation bucket. According to claim 1,
a supply pump disposed on a supply pipe connecting the storage bucket and the circulation bucket; and
Water filter; Humidifier further comprising. 7. The method of claim 6,
The residual water container includes a residual water high level sensor,
When a signal is received from the residual water high level sensor, the processor stops the operation of the humidifier and outputs a residual water container empty warning to the outside; the humidifier further comprising a. 7. The method of claim 6,
The humidifier further comprising a; when an OFF signal of the humidifier is input, the processor operates the drain member to discharge the water contained in the circulation water container to the residual water container. In the control method of a humidifier in which the storage bucket, the humidifying member and the circulation bucket are sequentially located,
receiving a low water level signal for the circulating bucket;
supplying the water from the storage bucket to the circulation bucket using a valve that selectively provides the water from the storage bucket to the circulation bucket;
receiving a high water level signal for the circulating bucket; and
Control method of a humidifier comprising a; controlling the valve so that the water in the storage bucket is not supplied.

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