KR20180052474A - Air conditioner apparatus - Google Patents

Abstract

The present invention relates to an air conditioning apparatus comprising: a first flowing chamber, wherein first air flows and a liquid desiccant is stored; a second flowing chamber, wherein second air flows and a liquid desiccant is stored; a first circulation module disposed in the first flow chamber, and sucking the liquid desiccant stored in the second flow chamber to discharge the sucked liquid desiccant to the first flow chamber; a second circulation module disposed in the second flow chamber, and sucking the liquid desiccant stored in the first flow chamber to discharge the sucked liquid desiccant to the second flow chamber; and a thermoelectric module interposed between the first and second circulation modules, and providing the first and second circulation modules with opposed heat sources. According to the present invention, provided is an advantage capable of continuously performing dehumidification or humidification in the first flow chamber in which indoor air flows without switching a flow direction of air sucked from an indoor space.

Description

[0001] Air conditioner apparatus [0002]

The present invention relates to an air conditioner apparatus.

Generally, an air conditioner device refers to a device that discharges contaminated air in a room, and sucks fresh, clean air out of the room and supplies it to the room.

An air conditioner without ventilation function circulates indoor air while cooling or heating indoor air. There is a problem that the indoor air quality is gradually lowered when air conditioning is performed only by indoor air.

In recent years, there has been an increasing number of cases of installing an air conditioner having a ventilation function for sucking outdoor air and discharging indoor air.

In a conventional air conditioning apparatus having a ventilation function, two heat exchangers are disposed, and each heat exchanger is operated alternately with a condenser or an evaporator. The conventional air conditioner having a ventilating function causes air to flow in four directions (outdoors, outdoor, indoor, indoor).

The ventilator having two heat exchangers has a complicated structure because it operates with a heat pump cycle of the refrigerant.

Korean Patent Publication No. 10-2010-0128152

An object of the present invention is to provide an air conditioner apparatus having a simple ventilation function using a liquid decanter.

An object of the present invention is to provide an air conditioner apparatus capable of continuously performing dehumidification or humidification in one chamber without switching the air flow path.

An air conditioner according to the present invention includes: a first flow chamber in which a first air flows and a liquid desiccant is stored; A second flow chamber in which a second air flows and a liquid desiccant is stored; A first circulation module disposed in the first flow chamber, for sucking the liquid decant stored in the second flow chamber and discharging the liquid decant into the first flow chamber; A second circulation module disposed in the second flow chamber, for sucking the liquid decant stored in the first flow chamber and discharging the liquid decant into the second flow chamber; And a thermoelectric module disposed between the first circulation module and the second circulation module and providing heat sources opposite to each other in the first circulation module and the second circulation module.

case; Further comprising a flow chamber partition for partitioning the interior of the case, wherein the first flow chamber is disposed on one side of the flow chamber partition, the second flow chamber is disposed on the other side of the flow chamber partition, May be disposed in the flow chamber partitions.

Wherein at least a portion of the first circulation module is in close contact with one side of the flow chamber partition in which the thermoelectric module is disposed and at least a portion of the second circulation module is in close contact with the other side of the flow chamber partition in which the thermoelectric module is disposed have.

A first collection chamber for storing a liquid desiccant of said first flow chamber; And a second recovery chamber for storing a liquid decant of the second flow chamber, wherein the first recovery chamber may be disposed below the first flow chamber.

The first flow chamber and the first recovery chamber may communicate with each other through a first recovery port.

The apparatus may further include a first recovery chamber partition for partitioning the interior of the first flow chamber to form the first recovery chamber, and the first recovery port may be disposed in the first recovery chamber partition.

The first collection chamber partitions may be inclined toward the first collection port.

A first collection chamber for storing a liquid desiccant of said first flow chamber; And a second recovery chamber for storing a liquid decant of the second flow chamber, and the second recovery chamber may be disposed below the second flow chamber.

And the second flow chamber and the second recovery chamber may communicate with each other through the second recovery port.

And a second recovery chamber partition for partitioning the inside of the first flow chamber to form the first recovery chamber, and the second recovery chamber may be disposed in the second recovery chamber partition.

And the second recovery chamber partition may be inclined toward the second recovery port.

The first circulation module includes a suction unit for sucking the liquid decant stored in the second recovery chamber; A discharging portion through which the liquid decant sucked in the suction portion is discharged; A connection part connecting the suction part and the discharge part; And a pump disposed in at least one of the suction unit, the discharge unit, and the connection unit and configured to cause the liquid decant to flow.

case; Further comprising a flow chamber partition for partitioning the interior of the case, wherein the first flow chamber is disposed on one side of the flow chamber partition, the second flow chamber is disposed on the other side of the flow chamber partition, May be disposed in the flow chamber partition and the suction portion may be connected to the interior of the second flow chamber through the flow chamber partition in the first flow chamber.

The second circulation module includes a suction unit for sucking the liquid decant stored in the first collection chamber; A discharging portion through which the liquid decant sucked in the suction portion is discharged; A connection part connecting the suction part and the discharge part; And a pump disposed in at least one of the suction unit, the discharge unit, and the connection unit and configured to cause the liquid decant to flow.

case; Further comprising a flow chamber partition for partitioning the interior of the case, wherein the first flow chamber is disposed on one side of the flow chamber partition, the second flow chamber is disposed on the other side of the flow chamber partition, May be disposed in the flow chamber partitions and the suction part may be connected to the interior of the first flow chamber through the flow chamber partitions in the second flow chamber.

The air conditioning apparatus having a ventilation function according to the present invention has the following effects.

First, there is an advantage that dehumidification or humidification can be continuously performed in the first flow chamber in which indoor air flows without changing the flow direction of the air sucked in the room.

Second, there is an advantage in that when performing dehumidification in the first flow chamber and humidification in the second flow chamber, the two flow chambers provide different heat sources through one thermoelectric module disposed in the flow chamber partition.

Third, since the liquid decant repeats dehumidification and humidification while circulating through the first flow chamber and the second flow chamber, there is an advantage that dehumidification or humidification can be continuously performed in any one of the flow chambers.

1 is a perspective view illustrating an air conditioner apparatus according to a first embodiment of the present invention.
2 is a perspective view showing the inside of FIG.
3 is a plan view of Fig.
4 is a perspective view of the circulation device shown in Fig. 2
5 is a perspective view of the thermoelectric module shown in FIG.
6 is an exemplary view showing the operation of the circulation device according to the first embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and the manner of achieving them, will be apparent from and elucidated with reference to the embodiments described hereinafter in conjunction with the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a perspective view showing the inside of FIG. 1, FIG. 3 is a plan view of FIG. 2, and FIG. 4 is a sectional view of the air conditioner of FIG. FIG. 5 is a perspective view of the thermoelectric module shown in FIG. 2, and FIG. 6 is an exemplary view illustrating the operation of the circulation device according to the first embodiment of the present invention.

Referring to the drawings, an air conditioner according to an embodiment of the present invention includes a case 100 and a circulation device 50 installed in the case 100 for circulating a liquid desiccant.

The case 100 is divided into two spaces through which air flows.

The case 100 includes a first flow chamber 10 in contact with the circulating liquid decant and the first air, a second flow chamber 20 in which the circulating liquid decant and the second air are in contact, A first recovery chamber 30 disposed below the first flow chamber 10 for recovering the liquid decant and a second recovery chamber 30 disposed below the second flow chamber 20 for recovering the liquid desiccant 40).

The circulator (50) circulates the liquid decant in the first flow chamber (10) and the second flow chamber (20). In this embodiment, the circulation device 50 discharges the liquid decant of the first flow chamber 10 to the second flow chamber 20, and the liquid desiccant of the second flow chamber 20 to the first flow chamber 20, (10).

A thermoelectric module (90) is disposed between the first flow chamber (10) and the second flow chamber (20) and provides a heat source to the circulation device (50). Dehumidification or humidification is provided in the first flow chamber 10 through the heat source provided in the circulation device 50 and humidification or dehumidification is provided in the second flow chamber 20. [

The first flow chamber 10 and the second flow chamber 20 may be separated from each other. In the present embodiment, the first flow chamber 10 and the second flow chamber 20 are formed by a flow chamber partition 101 partitioning the inside of the case 100 to the left and right.

The first flow chamber 10 further includes a first suction port 11 and a first discharge port 12 and the second flow chamber 20 has a second suction port 21 and a second discharge port 22 .

In the present embodiment, the first suction port 11 is an indoor suction port for sucking indoor air, and the first discharge port 12 is an indoor discharge port for discharging air-conditioned air to the room. In the present embodiment, the second suction port 21 is an outdoor suction port for sucking outdoor air, and the second discharge port 22 is an outdoor discharge port for discharging air-conditioned air to the outside.

The first air flows into the first flow chamber 10 through the first suction port 11 and then is discharged to the outside through the first discharge port 12. [

The second air flows into the second flow chamber 20 through the second suction port 21 and then is discharged to the outside through the second discharge port 22. [

A duct may be connected to the first suction port 11, the first discharge port 12, the second suction port 21, and the second discharge port 22, respectively.

When the first air is room air, the second air is outdoor air, and when the first air is outdoor air, the second air is indoor air.

A duct structure capable of selectively supplying indoor air or outdoor air to the suction side of the case 100 may be disposed. A duct structure capable of selecting and discharging air to the inside or outside of the case 100 on the discharge side of the case 100 can be disposed.

Therefore, it is possible to flow the air by "indoor suction-indoor discharge and outdoor suction-outdoor discharge", and air can flow through "indoor suction-outdoor discharge and outdoor suction-indoor discharge".

That is, either indoor air or outdoor air is selectively sucked through the first suction port (11) of the first flow chamber (10) and is discharged through the first discharge port (12) of the first flow chamber The sucked air can be discharged into the room or outdoors.

One of the outdoor air and the indoor air is selectively sucked through the second suction port 21 of the second flow chamber 20 and is discharged through the second discharge port 22 of the second flow chamber 20 The sucked air can be discharged outdoors or indoors.

The air sucked into the first flow chamber 10 can be dehumidified or humidified through the liquid desiccant. The air sucked into the second flow chamber 20 can be humidified or dehumidified through the liquid desiccant.

When dehumidification is performed in the first flow chamber 10, the second flow chamber 20 is humidified. On the other hand, when the first flow chamber 10 is formed in a manner as described above, the second flow chamber 20 is dehumidified.

The related description will be described in more detail when describing the circulation device.

The first recovery chamber 30 may be separated from the first flow chamber 10 and the second recovery chamber 40 may be separated from the second flow chamber 20. The first recovery chamber partition 102 partitioning the first flow chamber 10 into upper and lower portions and the second recovery chamber partition 104 partitioning the second flow chamber 20 upward and downward . The first recovery chamber partition 102 and the second recovery chamber partition 104 may be integrally formed. The first recovery chamber partition 102 is disposed on one side of the flow chamber partition 101 and the second recovery chamber partition 104 is disposed on the other side of the fluid chamber partition 101. [

The liquid decant may be stored in the first flow chamber 10 without the first recovery chamber 30, unlike the present embodiment. Also, the liquid decant may be stored in the second flow chamber 20 without the second recovery chamber 40.

The first recovery chamber partition (102) is provided with a first recovery port (103) for recovering the liquid decant of the first flow chamber (10) into the first recovery chamber (30) The recovery chamber partition 104 is provided with a second recovery port 105 for recovering the liquid decant of the second flow chamber 20 into the second recovery chamber 40.

The first recovery chamber partition (102) is inclined toward the first recovery port (103). The first collection port 103 is elongated in the air flow direction. The first collection port (103) communicates with the first collection chamber (30) disposed on the lower side.

When the first flow chamber 10 and the first recovery chamber 30 are separately formed, a flow path for guiding the liquid decanter is disposed in the first recovery port 103. Since the first flow chamber 10 and the first recovery chamber 30 are directly connected to each other in the present embodiment, the first recovery port 103 is connected to the first flow chamber 10 and the first recovery chamber 30 ).

The second recovery port 105 also communicates directly with the second flow chamber 20 and the second recovery chamber 40.

The first collection port 103 and the second collection port 105 are formed in a long slit shape.

The first recovery chamber partition 102 comprises a 1-1 recovery chamber partition 102-1 and a 1-2 recovery chamber partition 102-2, The 1-2 recovery chamber partition 102-2 forms a predetermined angle. The first collection port 103 is disposed at a boundary portion between the 1-1 recovery chamber partition 102-1 and the 1-2 recovery chamber partition 102-2.

Therefore, the liquid desiccant located above the 1-1 recovery chamber partition 102-1 and the 1-2 recovery chamber partition 102-2 includes the 1-1 recovery chamber partition 102-1 and 1-2 recovery And is guided to the first collection port 103 along the inclination of the chamber partition 102-2.

The second recovery chamber partition 104 also includes a 2-1 recovery chamber partition 104-1 and a 2-2 recovery chamber partition 104-2. The 2-1 recovery chamber partition 104-1 and the 2-2 recovery chamber partition 104-2 form a predetermined angle between the 2-1 recovery chamber partition 104-1 and the 2-2 recovery chamber 104-1, And the second recovery port 105 is disposed between the partitions 104-2. The liquid decant which is on the upper side of the 2-1 collection chamber partition 104-1 and the 2-2 collection chamber partition 104-2 is guided to the second collection port 105 along an inclination.

The circulation device 50 includes a first circulation module 60 disposed in the first flow chamber 10 and a second circulation module 70 disposed in the second flow chamber 20. The structures of the first circulation module 60 and the second circulation module 70 are the same and are arranged opposite to each other with respect to the flow direction of the air.

The first circulation module (60) is disposed on one side of the flow chamber partition (101), and the second circulation module (70) is disposed on the other side.

The first circulation module 60 includes a suction part 62 for sucking the liquid decant stored in the second recovery chamber 30 and a discharge part 62 for discharging the liquid decant sucked in the suction part 62 66 and a connecting portion 64 for connecting the suction portion 62 and the discharging portion 66 to each other and at least one of the suction portion 62 and the discharging portion 66 or the connecting portion 64, And a pump 68 for flowing the desiccant.

The suction portion 62, the discharge portion 66, and the connection portion 64 may be formed in the form of a pipe or a duct capable of flowing a fluid in a liquid state.

The suction unit 62 is disposed inside the first recovery chamber 30 and has an end located in the second recovery chamber 40 through the flow chamber partition 101.

That is, the first circulation module 60 is disposed in the first flow chamber 10, but sucks the liquid decant of the second flow chamber 20 and discharges the liquid to the first flow chamber 10. Likewise, the second circulation module 70 is disposed in the second flow chamber 20, but sucks the liquid decant of the first flow chamber 10 and discharges it to the second flow chamber 20.

In this embodiment, the pump 68 is disposed in the connection portion 64.

The connection portion 64 includes a first connection portion 64a that is orthogonal to the first suction portion 61 and the second suction portion 62 and that is disposed in the vertical direction and a second connection portion 64b that is perpendicular to the first connection portion 64a And a third connecting portion 64c that is orthogonal to the second connecting portion 64a and horizontally disposed in a direction away from the flow chamber partition 101. The second connecting portion 64b is disposed horizontally.

The discharge portion 66 is connected to the third connection portion 64c and disposed horizontally. The discharge portion 66 is disposed orthogonally to the third connection portion 64c. The discharge portion 66 is disposed in parallel with the second connection portion 64b.

A plurality of holes 67 through which the liquid decant is discharged are formed below the discharge portion 66.

The liquid desiccant drops down through the holes 67 and in this process comes into contact with the flowing air to provide dehumidification or humidification.

The second circulation module (70) is arranged symmetrically with the first circulation module (60).

The second circulation module 70 includes a suction unit 72 for sucking the liquid decant stored in the first recovery chamber 30 and a discharge unit 72 for discharging the liquid decant sucked in the suction unit 72 A connecting portion 74 connecting the suction portion 72 and the discharging portion 76 and at least one of the suction portion 72 and the discharging portion 76 or the connecting portion 74, And a pump 78 for flowing the desiccant.

The connection unit 74 includes a first connection unit 74a, a second connection unit 74b, and a third connection unit 74c. A hole 77 is formed in the discharge portion 76.

In the present embodiment, the thermoelectric module 90 is disposed in the flow chamber partition 101, and the connection portion 64 of the first circulation module 60 and the connection portion 74 of the second circulation module 74 Is heated or cooled by the thermoelectric module (90).

The thermoelectric module 90 is a device in which a thermoelectric element, on which heat is generated on one side and heat is generated on the other side due to the Peltier effect when an electric current is applied, is integrated. Generally, a thermoelectric device is manufactured by combining P type semiconductor and N type semiconductor. Since the structure of the thermoelectric element is a general technology to those skilled in the art, a detailed description thereof will be omitted.

When the connection portion 64 of the first circulation module 60 is cooled when a current is applied to the thermoelectric module 90, the connection portion 74 of the second circulation module 74 is heated. Conversely, when a current is applied to the thermoelectric module 90, the connection part 74 of the second circulation module 74 is cooled when the connection part 64 of the first circulation module 60 is heated.

The thermoelectric module 90 provides heat sources of different properties to the two connecting portions 64 and 74, through which the liquid desiccant can be cooled or heated. Since the components and functions of the liquid decanter are common to those skilled in the art, a detailed description thereof will be omitted.

When the liquid decanter is cooled, moisture in the air can be adsorbed. When the liquid desiccant is heated, adsorbed moisture can be released into the air.

The thermoelectric module 90 is disposed between the second connection portion 64b of the first circulation module 60 and the second connection portion 74b of the second circulation module 70 in this embodiment.

Hereinafter, an operation method of the air conditioner according to the present embodiment will be described in more detail.

First, a case of dehumidifying indoor air will be described.

In this embodiment, the first flow chamber 10 is flowed with indoor air, and the second flow chamber 20 is flowed with outdoor air.

When indoor air flows in the first flow chamber 10 and outdoor air flows in the second flow chamber 20, dehumidification is performed through the liquid desiccant in the first flow chamber 10, Thereby regenerating the liquid desiccant in the chamber 20.

The first circulation module 60 sucks the liquid decant of the second flow chamber 20 through the suction port 62 and the second circulation module 70 sucks the liquid decant of the first flow chamber 10 through the suction port 72, Inhale the liquid desiccant.

The thermoelectric module 90 cools the connecting portion 64 disposed in the first flow chamber 10 and dehumidifies the first flow chamber 10 to cool the connecting portion 64 disposed in the second flow chamber 10, (74).

A liquid decant circulated by the first circulation module 60 is cooled by the thermoelectric module 90 and a liquid decant circulated by the second circulation module 70 is supplied to the thermoelectric module 90, .

The liquid decant circulated by the first circulation module 60 is jetted from the discharge portion 66 to be in contact with the air in the first flow chamber 10 to adsorb moisture in the air.

The liquid desiccant circulated by the second circulation module 70 is jetted from the discharge portion 76 to be in contact with the air of the second flow chamber 20 and emits moisture that has been adsorbed into the air. The liquid desiccant of the second circulation module 70 is regenerated in a state capable of adsorbing moisture by releasing moisture adsorbed to the liquid desiccant through heating.

The liquid desiccant discharged from the first circulation module 60 is recovered to the first recovery chamber 30 and the liquid desiccant discharged from the second circulation module 70 is recovered to the second recovery chamber 40 .

Here, the liquid decanter recovered in the first recovery chamber 30 is in a state of adsorbing moisture, and is heated by the second circulation module 70 at the connection portion 74, and is discharged and regenerated.

In addition, the liquid decanter recovered in the second recovery chamber 40 is regenerated by releasing moisture. The liquid decanter is cooled by the first circulation module 60 and then discharged through the connection portion 64 to perform dehumidification.

As described above, the air conditioner according to the present embodiment repeats dehumidification and humidification while the liquid decant circulates through the first flow chamber 10 and the second flow chamber 20, There is an advantage that dehumidification can be performed.

The air conditioner according to the present embodiment continuously performs dehumidification in the first flow chamber 10 without changing the flow direction of the air and continuously humidifies or liquid desiccant regeneration in the second flow chamber 20 .

Next, the case of humidifying the indoor air will be described.

When the room air is humidified, the thermoelectric module 90 heats the connecting portion 64 of the first circulation module 60 and cools the connecting portion 74 of the second circulation module 70.

In this case, the liquid decant circulated through the first circulation module 60 is heated by the connection portion 64, and then discharged from the discharge portion 66 to the first flow chamber 10, and the first flow chamber 10 The moisture adsorbed in the liquid desiccant is released.

The liquid decant circulated through the second circulation module 70 is cooled in the connecting portion 74 and then discharged from the discharge portion 76 to the second flow chamber 20 and flows into the second flow chamber 10 ) In the air.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is to be understood that the invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

10: first flow chamber 20: second flow chamber
30: first collection chamber 40: second collection chamber
50: circulation device 60: first circulation module
70: second circulation module 90: thermoelectric module
100: Case 101: Flow chamber partition
102: first recovery chamber partition 103: second recovery chamber partition

Claims (15)

A first flow chamber in which the first air flows and a liquid desiccant is stored;
A second flow chamber in which a second air flows and a liquid desiccant is stored;
A first circulation module disposed in the first flow chamber, for sucking the liquid decant stored in the second flow chamber and discharging the liquid decant into the first flow chamber;
A second circulation module disposed in the second flow chamber, for sucking the liquid decant stored in the first flow chamber and discharging the liquid decant into the second flow chamber;
And a thermoelectric module disposed between the first circulation module and the second circulation module and providing heat sources opposite to each other in the first circulation module and the second circulation module. The method according to claim 1,
case; Further comprising a flow chamber partition for partitioning the interior of the case, wherein the first flow chamber is disposed on one side of the flow chamber partition, the second flow chamber is disposed on the other side of the flow chamber partition, And an air conditioning device disposed in the flow chamber partition. The method of claim 2,
Wherein at least a portion of the first circulation module is in close contact with one side of the flow chamber partition in which the thermoelectric module is disposed and at least a portion of the second circulation module is in contact with the other side of the flow chamber partition Harmonic device. The method according to claim 1,
A first collection chamber for storing a liquid desiccant of said first flow chamber;
And a second recovery chamber for storing a liquid decant of the second flow chamber,
Wherein the first collection chamber is disposed below the first flow chamber. The method of claim 4,
Wherein the first flow chamber and the first recovery chamber communicate with each other through a first recovery port. The method of claim 5,
Further comprising a first recovery chamber partition for partitioning the interior of the first flow chamber to form the first collection chamber, wherein the first collection port is disposed in the first collection chamber partition. The method of claim 6,
Wherein the first collection chamber partitions are disposed obliquely toward the first collection port. The method according to claim 1,
A first collection chamber for storing a liquid desiccant of said first flow chamber;
And a second recovery chamber for storing a liquid decant of the second flow chamber,
And the second recovery chamber is disposed below the second flow chamber. The method of claim 8,
And the second flow chamber and the second recovery chamber communicate with each other through a second recovery port. The method of claim 9,
Further comprising a second recovery chamber partition for partitioning the interior of the first flow chamber to form the first collection chamber, wherein the second collection port is disposed in the second collection chamber partition. The method of claim 10,
And the second recovery chamber partition is disposed to be inclined toward the second recovery port. The method of claim 4,
The first circulation module includes:
A suction unit for sucking the liquid decant stored in the second recovery chamber;
A discharging portion through which the liquid decant sucked in the suction portion is discharged;
A connection part connecting the suction part and the discharge part;
And a pump disposed in at least one of the suction unit, the discharge unit, and the connection unit and configured to cause the liquid decant to flow. The method of claim 12,
case; Further comprising a flow chamber partition for partitioning the interior of the case, wherein the first flow chamber is disposed on one side of the flow chamber partition, the second flow chamber is disposed on the other side of the flow chamber partition, Is disposed in the flow chamber partition,
Wherein the suction portion is connected to the interior of the second flow chamber through the flow chamber partition in the first flow chamber. The method of claim 8,
The second circulation module includes:
A suction unit for sucking the liquid decant stored in the first recovery chamber;
A discharging portion through which the liquid decant sucked in the suction portion is discharged;
A connection part connecting the suction part and the discharge part;
And a pump disposed in at least one of the suction unit, the discharge unit, and the connection unit and configured to cause the liquid decant to flow. 15. The method of claim 14,
case; Further comprising a flow chamber partition for partitioning the interior of the case, wherein the first flow chamber is disposed on one side of the flow chamber partition, the second flow chamber is disposed on the other side of the flow chamber partition, Is disposed in the flow chamber partition,
Wherein the suction portion is connected to the interior of the first flow chamber through the flow chamber partition in the second flow chamber.

Images