KR102541587B1 - Movable air conditioner - Google Patents

Abstract

The present invention relates to a mobile air conditioner, and more particularly, to a mobile air conditioner capable of cooling a condenser using condensate generated when indoor air is air-conditioned.
The present invention, the case forming the appearance; a base plate coupled to the lower portion of the case; a condenser disposed on the base plate; a first blowing unit disposed adjacent to the condenser; a partition plate partitioning a space in which the condenser and the first blowing unit are disposed; an evaporator disposed above the partition plate; a second blowing unit disposed adjacent to the evaporator; a water storage groove provided on the partition plate to provide a space in which the condensed water that has been condensed and dropped from the evaporator is stored; and a condensate drop hole disposed inside the water storage groove to allow the condensed water stored in the water storage groove to pass through the partition plate and fall.

Description

Mobile air conditioner {MOVABLE AIR CONDITIONER}

The present invention relates to a mobile air conditioner, and more particularly, to a mobile air conditioner capable of cooling a condenser using condensate generated when indoor air is air-conditioned.

In general, a mobile air conditioner has a form in which components such as a compressor, an evaporator (generally an indoor heat exchanger), an expansion valve, and a condenser (generally an outdoor heat exchanger) are integrally included in a single product.

A mobile air conditioner can be manufactured as a single product by arranging an evaporator (indoor heat exchanger) and a condenser (outdoor heat exchanger) in a partitioned space so that it can be easily moved and installed.

Unlike general air conditioners in which an outdoor unit is provided separately, a mobile air conditioner has an advantage in that an evaporator and a condenser are installed and manufactured in a single product, so that consumers can install them by themselves and that mobile installation is easy.

In general, a mobile air conditioner performs only a cooling function of cooling indoor air, but a cooling cycle and a heating cycle may be switched by enabling reverse circulation of a refrigerant.

In recent years, the development and distribution of mobile air conditioners having moving wheels attached to the bottom so that users can easily move them have been actively developed.

Since the mobile air conditioner is easy to move and install, the user can easily place and install the mobile air conditioner in a desired place without the help of an expert who has acquired separate installation skills.

The mobile air conditioner does not require separate construction for installation, and the user can easily move and install the mobile air conditioner, thereby saving installation costs.

The mobile air conditioner may be used in a state of being mounted on the floor rather than being installed on a wall or ceiling as in the prior art. Therefore, after the evaporator partitions the space inside the mobile air conditioner vertically so that the air-conditioned air can be discharged upward, the evaporator is disposed on the upper side and the condenser is disposed on the lower side.

The condenser is a part where the refrigerant, which has become a high-temperature and high-pressure gaseous state in the compressor, flows and exchanges heat with the air passing through the condenser to condense the refrigerant. Therefore, the temperature of the air that exchanges heat with the refrigerant rises, and the air that exchanges heat with the refrigerant is discharged to the outdoors.

It is important to cool the condenser to improve cooling efficiency. This is because the refrigerant cooled in the cooler flows through the evaporator through the condenser and discharges the cooled air into the room while passing through the evaporator.

Mobile air conditioners tend to be miniaturized so that they can be easily moved and installed. Parts constituting the mobile air conditioner are efficiently arranged inside the mobile air conditioner so that numerous components can be installed inside the miniaturized product.

The accommodating space provided inside the mobile air conditioner is very narrow, and since numerous parts for driving the mobile air conditioner are installed, it is difficult to cool the condenser. Therefore, a method for efficiently cooling the condenser is required.

Publication No. 10-2008-0003524

An object of the present invention is to efficiently cool heat generated from a condenser installed in a receiving space inside a mobile air conditioner.

Therefore, the present invention is to efficiently cool the heat generated in the condenser by allowing condensed water to fall into the condenser and contact the condenser.

In addition, the present invention is to provide a structure that allows condensed water generated in the evaporator to uniformly fall into the lower condenser.

The present invention in order to solve the above problems, the case forming the exterior; a base plate coupled to the lower portion of the case; a condenser disposed on the base plate; a first blowing unit disposed adjacent to the condenser; a partition plate partitioning a space in which the condenser and the first blowing unit are disposed; an evaporator disposed above the partition plate; a second blowing unit disposed adjacent to the evaporator; a water storage groove provided on the partition plate to provide a space in which the condensed water that has been condensed and dropped from the evaporator is stored; and a condensate drop hole disposed inside the water storage groove to allow the condensed water stored in the water storage groove to pass through the partition plate and fall.

Preferably, the condensate falling hole is arranged to overlap with the evaporator directly above the evaporator, and more preferably, the condensed water falling hole is arranged to overlap with the refrigerant pipe of the evaporator.

In addition, the condensed water falling hole may include an inlet rib protruding upward from the water storage groove and an outlet rib protruding downward from the water storage groove.

The mobile air conditioner according to the present invention may further include a condensate drain hole disposed inside the water storage groove and having a larger diameter than the condensate drop hole.

The condensate falling hole has an inlet rib protruding from the top of the water storage groove, and the condensate drain hole has an inlet rib that protrudes from the top of the water storage groove, and the inlet rib of the condensate drain hole is higher than the inlet rib of the condensate falling hole. It is desirable to protrude.

According to the mobile air conditioner according to the present invention, after the condensed water generated in the evaporator is stored, it is allowed to fall into the lower condenser so that the condenser can be cooled using the condensed water, so that the condenser can be cooled by a water cooling method. bring

In addition, the mobile air conditioner according to the present invention blows the condensed water that has fallen back to the condenser using a splash fan, thereby improving the cooling effect of the condenser.

1 is a front perspective view showing an external configuration of a mobile air conditioner according to an embodiment of the present invention.
2 is a rear perspective view showing an external configuration of a mobile air conditioner according to an embodiment of the present invention.
3 is a view showing a state in which the installation kit and the pipe part are mounted in FIG.
Figure 4 is an exploded perspective view showing the internal configuration of the mobile air conditioner according to an embodiment of the present invention.
5 is a perspective view of a base plate on which parts are installed in a mobile air conditioner according to an embodiment of the present invention.
6 is a perspective view showing a partition plate of a mobile air conditioner according to an embodiment of the present invention.
7 is a cross-sectional view showing a partition plate of a mobile air conditioner according to an embodiment of the present invention.
8 is a perspective view showing a base plate of a mobile air conditioner according to an embodiment of the present invention.
FIG. 9 is a view showing a state in which a splash fan is installed on the base plate of FIG. 8 .
10 is a perspective view of a splash impeller constituting the splash fan of FIG. 9 .
11 is a side view of a splash impeller constituting the splash fan of FIG. 9 .
12 is a side view showing a state in which a condenser is installed on the base plate of FIG. 8 .
Fig. 13 is a plan view of Fig. 12;
14 is a conceptual diagram illustrating a state in which condensed water is supplied to a condenser by a splash fan of a mobile air conditioner according to an embodiment of the present invention.
15 is a conceptual diagram illustrating an installation state of a condenser and a splash fan of a mobile air conditioner according to an embodiment of the present invention.
FIG. 16 is a conceptual diagram illustrating still another embodiment of FIG. 15 .
17 is a conceptual diagram illustrating a state in which air flows inside a mobile air conditioner according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings.

In this specification, singular expressions include plural expressions unless the context clearly dictates otherwise.

In describing the embodiments disclosed in this specification, if it is determined that detailed descriptions of related known technologies may obscure the gist of the embodiments disclosed in this specification, the detailed descriptions thereof will be omitted.

The accompanying drawings are only for easy understanding of the embodiments disclosed in this specification, and the technical idea disclosed in this specification is not limited by the accompanying drawings, and all changes and equivalents included in the spirit and technical scope of the present invention It should be understood to include water or substitutes.

1 is a front perspective view showing the external configuration of an embodiment of a mobile air conditioner 10 according to the present invention, and FIG. 2 is a rear perspective view showing the external configuration of an embodiment of a mobile air conditioner 10 according to the present invention, FIG. 3 is a view showing a state in which the installation kit 1200 and the pipe part 1300 in FIG. 2 are mounted.

In order to achieve the above object, the mobile air conditioner 10 according to the present invention may include a case and an accommodation space formed inside the case.

The case may consist of a single case forming the front, rear and side exteriors, but the front case 1000 forming the front exterior and the rear case forming the rear exterior so that assembly and disassembly of the product can be facilitated. (1100) may be provided.

The lower outer portion of the front and rear cases 1000 and 1100 forms a lower exterior, and the base plate 100 supporting components installed inside the front and rear cases 1000 and 1100 can be combined with the lower portions of the front and rear cases 1000 and 1100. There is (front may be defined based on the direction toward the user when the mobile air conditioner 10 is disposed).

In general, the mobile air conditioner 10 allows the refrigerant to flow inside the mobile air conditioner 10 and is configured to exchange heat twice with surrounding air.

The mobile air conditioner 10 is provided with first and second heat exchangers 500 and 800 in an internal accommodation space so that the refrigerant and the surrounding air can exchange heat. By installing the first and second heat exchangers 500 and 800 in each receiving space, the portable air conditioner 10 can be made compact and movable.

Accordingly, the accommodating space defined by the front and rear cases 1000 and 1100 and the base plate 100 may be divided into an upper second accommodating space and a lower first accommodating space by the partition plate 600 .

An evaporator 800 and a second blowing unit 700 may be installed adjacent to the evaporator 800 in the second accommodating space, and the evaporator 800 and the second blowing unit 700 may be mounted on the partition plate 600 .

In addition, the condenser 500 and the first blowing unit 300 may be installed adjacent to the condenser 500 in the first accommodating space, and the condenser 500 and the first blowing unit 300 may be mounted on the base plate 100 .

The top surfaces of the condenser 500 and the first blower unit 300 mounted on the base plate 100 may support the bottom surface of the partition plate 600 to improve structural stability.

In the case 1000 or 1100, a suction port through which external air can flow into the accommodation space, an exhaust port 1180 through which air inside the accommodation space can be discharged to the outside, and a discharge port 1041 may be formed. And, the inlet may be provided with a second inlet 1110 communicating with the second accommodating space and a first inlet 1130 communicating with the first accommodating space.

Condensation and evaporation of the refrigerant occur separately in the receiving space divided into upper and lower parts, and heat exchange may occur. For example, the condenser 500 operates as a condenser and the evaporator 800 operates as an evaporator, and may be installed in the first accommodation space and the second accommodation space, respectively. The first and second heat exchangers 500 and 800 are connected to the compressor 202 and the refrigerant pipe 400 so that the refrigerant can flow.

In this way, the mobile air conditioner 10, in which components such as an evaporator, a condenser, and a compressor are integrated into a single product, can be configured in a compact size, and thus has an advantage of easy mobile installation.

As shown in FIGS. 1 and 2 , the mobile air conditioner 10 according to the present invention includes a front case 1000 forming a front exterior and a rear case 1100 forming a rear exterior. Appearance can be formed schematically.

The front case 1000 may form the skeleton of the first half, and may partially form the appearance of the top and left and right sides.

The rear case 1100 may be provided to partially form the appearance of the upper and left and right sides as well as the appearance of the second half of the mobile air conditioner 10 according to the present invention.

A pipe part 1300 for discharging heat-exchanged air outdoors (outside a building) may be connected and installed to the rear case 1100 . The pipe part 1300 may be installed to communicate with the upper and lower second accommodating space or the first accommodating space, and the pipe part 1300 may be installed to communicate with the accommodating space in which a heat exchanger operating as a condenser is installed.

Referring to the case where the mobile air conditioner 10 operates for cooling, the high-temperature, high-pressure refrigerant that has passed through the compressor 202 and the air whose temperature has risen through heat exchange in the condenser pass through the pipe 1300. to be discharged outdoors. Therefore, the pipe part 1300 is installed to communicate with the receiving space in which the heat exchanger operating as the condenser is installed.

Below, as shown, the condenser 500 installed in the first accommodating space is operated as a condenser, so that the mobile air conditioner 10 is driven as a cooler.

The piping unit 1300 is installed to communicate with the accommodation space, and may be provided with a piping pipe 1310, a piping nozzle 1320, a piping connector 1330, and a piping grill 1340.

The piping pipe 1310 is made of a long cylindrical tube and guides the flow of exhaust, and the piping nozzle 1320 is an end that guides the exhaust flowing through the exhaust pipe to be finally discharged.

The piping pipe 1310 is preferably made of a flexible material or shape, so that it can be bent.

Further, the pipe connector 1330 is provided between the rear case 1100 and the pipe pipe 1310, and guides one end of the pipe pipe 1310 to be mounted on the rear case 1100.

An exhaust port 1180 through which air in the first accommodating space can be discharged may be formed in the lower part of the rear case 1100, and one end of the pipe pipe 1310 may be connected to the exhaust port 1180 by the pipe connector 1330. there is.

The pipe part 1300 is for discharging air that has undergone heat exchange in the accommodation space to the outdoors, and preferably has one end connected to the rear case 1100 and the other end exposed to the outdoors.

The other end of the pipe part 1300 can be easily exposed to the outdoors through a window frame. This is because the window is formed to communicate indoors and outdoors and is configured to be easily opened and closed.

That is, the window is opened as much as the diameter of the other end of the pipe part 1300, and the other end of the pipe part 1300 is exposed to the outdoors through the window open gap. This is because the other end of the pipe part 1300 can be exposed to the outdoors without perforating the wall.

However, when the other end of the pipe part 1300 is mounted on the window frame, an installation kit 1200 capable of fixing the other end of the pipe part 1300 to the window frame and sealing the window gap is required.

The installation kit 1200 is a device for fixing the other end of the pipe part 1300 so that the other end of the pipe part 1300 does not move while blocking the opening of the window corresponding to the diameter of the pipe part 1300.

Therefore, the installation kit 1200 may be configured in a rectangular shape corresponding to the shape of the window gap, and a through hole into which the other end of the pipe part 1300 may be inserted may be formed.

In order to facilitate storage and transportation of the installation kit 1200, it is preferable that a plurality of plates are slidably fastened to each other so that the length thereof can be adjusted.

The piping part 1300 and the installation kit 1200 constituting the mobile air conditioner 10 are parts constituting the exterior of the mobile air conditioner 10 and may be operated separately from the mobile air conditioner 10 .

When storing and moving the portable air conditioner 10, the piping 1300 and the installation kit 1200 are placed in the rear case 1100 to facilitate storage and movement of the piping 1300 and the installation kit 1200. It can be configured so that it can be mounted on.

For example, as shown, the installation kit 1200 is inserted into the installation kit accommodating part 1170 formed in the rear case 1100 so that the mobile air conditioner 10 and the installation kit 1200 can move together. there is.

4 is an exploded perspective view of the configuration of the mobile air conditioner according to the present invention.

As shown, the central portion of the front case 1000 may be provided so as to protrude more toward the front to improve appearance quality. Therefore, when viewed from the side, the front case 1000 may be formed to have a rounded curvature as a whole. This is to improve the appearance quality by configuring the appearance of the mobile air conditioner 10 in a round shape.

A discharge unit 1041 may be formed on the top of the case.

A discharge hole 1044 penetrating the discharge portion 1041 is formed in the discharge portion 1041 so that when the discharge portion 1041 is provided in the case, the inside and outside of the case may communicate. The lower part of the discharge port 1044 is in communication with the blowing nozzle hole 727 to be described below, and the discharge port 1044 is formed long to the left and right to form a square shape, and the discharge area of the discharge port 1044 through which air is discharged can be secured. there is.

The discharge part 1041 may be formed in a separate discharge frame 1040 and the discharge part 1041 may be provided on the upper part of the case by mounting the discharge frame 1040 on the upper part of the case. Alternatively, the discharge unit 1041 may be formed directly on the upper portion of the case without being configured in a separate discharge frame 1040 .

Whether the discharge part 1041 is formed as a separate frame or integrally formed with the case, the discharge part 1041 is a part through which the air-conditioned air is discharged from the accommodation space, and is formed on the top of the mobile air conditioner 10. desirable. This is in consideration of the fact that the generally movable mobile air conditioner 10 is disposed on the floor indoors.

The discharge part 1041 is provided at the top of the case so that the air-conditioned air is discharged upward, and the discharge port 1044 has the discharge port 1044 to discharge the air-conditioned air toward the front side of the mobile air conditioner 10 as described below. A discharge louver 750 may be additionally provided.

An operation unit 1020 may be provided on the top of the case. In order to conveniently operate the mobile air conditioner 10 disposed on the floor, the operation unit 1020 is preferably disposed above the mobile air conditioner 10 .

The operation unit 1020 is installed for the user to operate the mobile air conditioner 10, and a plurality of buttons may be provided here. Although not separately shown in the drawing, the control unit 1020 may include a control panel exposed on the outside and a PCB device installed under the control panel.

The control unit 1020 may be directly installed in the case, but may be mounted in a separate case capable of accommodating the control unit 1020 and installed in the case as one module.

Considering that the discharge unit 1041 and the operation unit 1020 are disposed above the mobile air conditioner 10, the discharge unit 1041 and the operation unit 1020 may be mounted on the top of the case. It may be configured in the frame of.

The rear case 1100 may be coupled to the front case 1000 . Considering that the rear case 1100 and the front case 1000 are coupled, the front end of the rear case 1100 may be molded into a shape corresponding to the rear end of the front case 1000 .

That is, when the rear ends of the left and right sides of the front case 1000 have a rounded curvature or are inclined, the front ends of the left and right sides of the rear case 1100 have a rounded curvature corresponding to the rear ends of the left and right sides of the front case 1000. It can be made or beveled.

A second intake port 1110 penetrating the inside and outside of the second accommodating space may be formed on the upper portion of the rear case 1100 . The second inlet 1110 serves as a passage through which indoor air is sucked into the second accommodating space.

The second inlet 1110 may be formed in various shapes, but is preferably formed in a rectangular shape in order to secure a sufficient area for the second inlet 1110 .

A second suction filter frame 1122 may be further provided in the second suction port 1110 to support the second suction filter 1124 .

The second suction port 1110 may be shielded by the second suction grill 1120 . Indoor air may pass through the second suction grill 1120 and be introduced into the accommodation space. Accordingly, a plurality of holes through which indoor air can pass may be formed through the second suction grill 1120 .

The second suction grill 1120 is preferably formed to have a size corresponding to that of the second suction port 1110 so as to facilitate the inflow of indoor air.

A second suction filter 1124 may be installed in the second suction port 1110 . The second suction filter 1124 filters foreign substances in the air introduced through the second suction grill 1120, and is preferably formed to have a size corresponding to that of the second suction port 1110.

The mobile air conditioner 10 forms an evaporator (indoor heat exchanger) and a condenser (outdoor heat exchanger) as one product so that it can be easily moved and installed. Therefore, after partitioning the accommodation space provided inside the case, an evaporator is disposed in one partitioned space and a condenser is disposed in the other space.

Since the mobile air conditioner 10 is used while mounted on the floor, unlike conventional air conditioners installed on walls or ceilings, the accommodation space provided inside the case is divided up and down, and then the evaporator is placed on the top. It is preferable to place a condenser at the bottom. This is to efficiently circulate indoor air by discharging air-conditioned air from the upper side of the mobile air conditioner 10 disposed on the floor.

Among the upper and lower accommodating spaces, it is preferable that the lower first accommodating space has a larger volume than the second accommodating space.

This is to ensure structural stability so that the mobile air conditioner 10 does not fall over when the mobile air conditioner 10 is moved or mounted by allowing more parts to be installed at the lower portion while securing the volume of the accommodation space. .

Therefore, in the mobile air conditioner 10 according to the embodiment of the present invention, the rear surface of the rear case 1100 may be formed stepwise. Specifically, the front and rear lengths of the rear case 1100 are different from each other in the upper part and the latter part. That is, the front and rear length of the lower part of the rear case 1100 may be larger than the front and rear length of the upper part.

As the front and rear lengths of the lower and upper parts of the rear case 1100 are different, a stepped surface may be formed in the center of the rear case 1100, but as shown, the stepped surface is not formed to improve the appearance quality. It is preferable to form a curved surface between the lower part and the upper part of the rear case 1100 so as not to

A first inlet 1130 is formed in the lower part of the rear case 1100 so that indoor air can be sucked into the first accommodating space.

A first suction filter frame 1142 may be further provided in the first suction port 1130 to support the first suction filter 1144 .

The first suction port 1130 may be shielded by the first suction grill 1140 . The first suction grill 1140 guides indoor air to be sucked into the first accommodating space and at the same time serves to prevent the inflow of foreign substances from the outside.

A first suction filter 1144 may be installed in the first suction port 1130 . The first suction filter 1144 filters foreign substances in the air introduced through the first suction grill 1140, and is preferably formed to have a size corresponding to that of the first suction port 1130.

5 is a perspective view showing a state in which parts are installed on the base plate 100 according to an embodiment of the present invention.

The lower exterior of the mobile air conditioner 10 of the present invention may be formed by the base plate 100. The base plate 100 is coupled to the lower ends of the front case 1000 and the rear case 1100 and supports a number of parts to be described below, and as shown, may be formed in a rectangular shape.

A plurality of moving wheels 150 are installed on the bottom surface of the base plate 100 . One moving wheel 150 may be installed at each corner of the rectangular base plate 100 so that the mobile air conditioner 10 can be easily moved.

Since the moving wheels 150 support each corner of the base plate 100, the mobile air conditioner 10 may not fall when moving.

A condenser 500 may be installed at the center of the upper surface of the base plate 100 . The condenser 500 may include a first refrigerant pipe 510 through which refrigerant may flow and a first heat dissipation plate 520 .

The first heat dissipation plate 520 may be provided in plurality in a thin plate shape, and the first refrigerant pipe 510 may be formed to pass through the first heat dissipation plate 520 .

The first heat dissipation plate 520 is connected to the first refrigerant pipe 510 to increase the surface area of the first refrigerant pipe 510 so that the air passing through the condenser 500 and the inside of the first refrigerant pipe 510 flow. The heat exchange of the refrigerant may be actively performed.

The first refrigerant pipe 510 and the first heat dissipation plate 520 may be formed of a material having excellent thermal conductivity, such as copper.

As shown, the condenser 500, which operates as a condenser, may be installed to cross the front and rear at the center of the base plate 100. This is to ensure that the air introduced through the first intake port 1130 disposed at the rear side passes through the condenser 500 and is then discharged to the rear side.

Air introduced into the first accommodating space through the first inlet 1130 formed at the bottom of the rear case 1100 passes through the condenser 500 and exchanges heat with the refrigerant flowing inside the condenser 500 . Air that has undergone heat exchange while passing through the condenser 500 is discharged to the outdoors through the pipe part 1300 .

Since the condenser 500 is disposed to cross the front and rear sides of the first accommodating space in the central portion, the first accommodating space may be divided into left and right sides by the condenser 500 . At this time, the space on one side may be defined as a first suction space through which outside air is sucked, and the space on the other side may be defined as a first discharge space through which air-conditioned air is discharged.

A first suction port 1130 may be formed at one side of the lower part of the rear case 1100 so that outside air can be sucked into the first suction space. In addition, an exhaust port 1180 may be formed on the other side of the lower part of the rear case 1100 so that the air-conditioned air can be discharged to the first discharge space.

The first blowing unit 300 may be disposed adjacent to the condenser 500 in the first discharge space. The air whose temperature has risen while passing through the condenser 500 is changed in direction by the first blowing unit 300 and may be discharged to the outside through the exhaust port 1180 .

The exhaust port 1180 may be formed to pass vertically through the lower part of the rear case 1100 so that the first discharge space and the outside can communicate with each other. This is to efficiently form a passage through which the air heated by the condenser 500 operating as a condenser can be discharged to the outside. That is, it is preferable to form the exhaust port 1180 vertically in consideration of the positions of the mobile air conditioner 10 and the window frame disposed on the floor.

The exhaust port 1180 is connected to the first air outlet 324 and is a part to which the piping pipe 1310 is fastened so that the air heat-exchanged in the condenser 500 is discharged to the outdoors. Therefore, it is preferable that the exhaust port 1180 has a size and shape corresponding to one end of the piping pipe 1310.

A compression unit 200 may be installed in the first suction space. This is to efficiently utilize the space by arranging the compression unit 200 in a position where it does not interfere with the condenser 500 and the first blowing unit 300 in the first accommodating space. In addition, since the compression unit 200 is disposed in the first suction space, the compressor 202 can be cooled by air sucked in in large quantities through the first suction port 1130 .

The compression unit 200 may include a compressor 202 and a compressor frame 204 supporting the compressor 202 . The compressor frame 204 may be provided in a triangular shape in consideration of space efficiency and support rigidity of the compressor 202 mounted on the base plate 100 .

An accumulator 203 may be installed next to the compressor 202 . The accumulator 203 serves to filter out the liquid refrigerant so that only gaseous refrigerant flows into the compressor 202 .

Although not shown in the drawings, a condensate detection device may be installed in the base plate 100 . The condensate detection device is a device that detects when the amount of condensate accumulated on the upper surface of the base plate 100 exceeds a certain amount.

When the condensate detection device detects more than a certain amount of condensate, it can generate a notification sound or display it externally.

A support angle 950 may be installed on the base plate 100 in close contact with the compression unit 200 . That is, the support angle 950 is vertically installed on the base plate 100 to support a load acting laterally on the compression unit 200 .

A first blowing unit 300 may be installed on one side of the condenser 500 . The first blowing unit 300 may include a first blowing guide, a first blowing orifice 323 , a first blowing motor 330 and a first impeller 340 . One side of the first blower unit 300 is provided with a first tuyere 324 through which the air introduced into the first blower unit 300 is discharged, and the first tuyere 324 is provided to prevent foreign matter from entering from the outside. A first ventilation grill 310 may be provided.

A first blowing orifice 323 may be disposed close to the first condenser 500 . The first blowing orifice 323 may support a plurality of parts such as a second blowing orifice 722 and a second blowing guide 721 to be described below, and the first blowing air passing through the condenser 500 is blown. It is guided into the unit 300.

A first blowing guide 322 is coupled to one side of the first blowing orifice 323 . The first blowing guide 322 guides the flow of air to the first blowing hole 324 together with the first blowing orifice 323 .

A first impeller 340 for forcing the flow of air is positioned between the first blowing orifice 323 and the first blowing guide 322 . The first impeller 340 rotates by the first blowing motor 330 and discharges air to the first tuyere 324 .

The first tuyere 324 is connected to the exhaust duct 1180 formed in the rear case 1100, and the air introduced into the first blower unit 300 by the rotation of the first blower motor 330 is blown through the first tuyere 324. It can be discharged to the outside through the exhaust port 1180 connected to.

6 is a perspective view showing a partition plate of the mobile air conditioner 10 according to an embodiment of the present invention, and FIG. 7 is a cross-sectional view showing the partition plate of the mobile air conditioner according to an embodiment of the present invention.

A partition plate 600 is installed in the center of the accommodation space. As shown, the partition plate 600 may be formed in a rectangular shape.

The partition plate 600 serves to collect condensate generated from the evaporator 800 to be described below, supports a number of parts, and divides the inner space of the mobile air conditioner 10 up and down. can do.

Looking more specifically at the partition plate 600, air conditioners are generally divided into an outdoor heat exchanger and an indoor heat exchanger. and the indoor heat exchanger side.

That is, a condenser corresponding to the outdoor heat exchanger is disposed in the first accommodating space disposed below the partition plate 600, and an evaporator corresponding to the indoor heat exchanger is disposed in the second accommodating space disposed above the partition plate 600.

As shown, the partition plate 600 has a substantially rectangular shape corresponding to the formation of the cross section of the accommodating space, and is installed in the central portion between the front case 1000 and the rear case 1100, so that the front case 1000 And the receiving space formed between the rear case (1100) is divided up and down.

On the upper surface of the partition plate 600, a plurality of second bottom partition ribs 602 are formed. The second bottom partitioning rib 602 forms a space in which condensed water can flow by allowing a plurality of chambers to be formed on the upper surface of the partition plate 600 .

Specifically, a plurality of second bottom partitioning ribs 602 are formed on the upper surface of the partition plate 600 at equal intervals. These second bottom partitioning ribs 602 are integrally formed with the partition plate 600, It may protrude upward from the upper surface of the partition plate 600 .

The second bottom partition rib 602 prevents a number of parts such as the evaporator 800 installed on the upper part of the partition plate 600 from being in close contact with the upper surface of the partition plate 600, and is generated in the evaporator 800. A predetermined space is formed so that the condensed water that has fallen can easily flow on the upper surface of the partition plate 600 .

In the partition plate 600, a water storage groove 601 is disposed in which the condensed water generated in the evaporator 800 is collected. The water storage groove 601 is formed in the shape of a concave groove on the upper surface of the partition plate 600, and is arranged so that condensed water formed in the evaporator 800 can be collected into the water storage groove 601 by natural drainage.

At this time, it is preferable that the position of the water storage groove 601 is overlapped with the upper part of the condenser 500 disposed under the partition plate 600. This is to allow the condensed water stored in the water storage groove 601 to fall into the condenser 500.

Inside the water storage groove 601, a plurality of condensed water drop holes 604 are formed vertically through. The condensate falling hole 604 serves to allow the condensed water generated in the evaporator 800 to move to the lower side of the partition plate 600 and fall into the condenser 500 .

A plurality of condensed water dropping holes 604 are provided, and it is preferable that the arrangement position be directly above the evaporator 800. This is to ensure that the condensed water falling through the condensed water falling hole 604 directly contacts the evaporator 800 .

The condensed water falling hole 604 is preferably arranged so as to be aligned directly above the first refrigerant pipe 510 so that the falling condensed water can directly contact the first refrigerant pipe 510 of the evaporator.

In addition, it is preferable that the diameter of the condensed water dropping hole 604 corresponds to the diameter of the first refrigerant pipe 510 . This is to guide the falling range of the condensed water falling through the condensed water falling hole 604 to the first refrigerant pipe 510 .

In addition, in order to uniformly drop the condensed water through the plurality of condensed water dropping holes 604, each condensed water dropping hole 604 preferably has an inlet rib 604a. The inlet rib 604a is formed to protrude from the bottom surface of the water storage groove 601 at a certain height. When the condensed water stored in the water storage groove 601 rises above the height of the inlet rib 604a, the condensed water can fall uniformly through the plurality of condensed water dropping holes 604.

In addition, the condensate drop hole 604 may further include an outlet rib 604b protruding downward. The outlet rib 604b serves to guide the falling direction of the condensed water. This is to prevent condensed water from flowing along the lower surface of the partition plate 600 due to the influence of air flow in a state where the condensed water does not fall and hangs at the lower end of the condensed water falling hole 604.

In addition, an exit groove 604c may be formed together with the exit rib 604b. Like the outlet ribs 604b, the outlet concave 604c serves to prevent condensed water from flowing while remaining on the bottom surface of the partition plate 600.

The outlet ribs 604b and the outlet grooves 604c provided on the bottom surface of the partition plate 600 serve as guides for guiding condensate falling. These serve to induce the condensed water moved to the lower surface of the partition plate 600 to fall directly without flowing to other parts.

However, as described above, in order to limit the falling range of condensate to a certain position, the diameter of the condensate falling hole cannot be increased.

However, when the diameter of the condensate falling hole is small, the condensate falling hole may be blocked by foreign substances or by freezing. If the condensate drop hole is blocked, the condensate stored in the partition plate may leave the water storage groove and flow to other parts.

In order to prevent this, it is preferable to further include a condensate drain hole 605 having a larger diameter than the diameter of the condensate falling hole.

The condensed water drainage hole 605 is disposed inside the water storage groove 601 like the condensed water falling hole 604, and is preferably disposed in a region immediately above the condenser 500.

In addition, the condensate drain hole 605 is also provided with an inlet rib 605a discharged to the upper part of the water storage groove 601.

By the way, it is preferable that the inlet rib 605a of the condensate drain hole 605 is formed higher than the height of the inlet rib 604a of the condensate drop hole 604. This is to allow the condensate to fall through the condensate drain hole 605 when the condensate does not fall smoothly through the condensate drop hole 604 .

Similar to the condensate drop hole 604, the bottom of the condensate drain hole 605 may also have an outlet rib 605b and an outlet groove 605c.

Meanwhile, a plurality of areas may be provided in the partition plate 600 so that components installed in the second accommodating space may be installed while avoiding interference.

For example, a pipe passage hole 624 through which the refrigerant pipe 400 passes, a control box mounting hole 620 formed to penetrate the partition plate 600 so that the control box 900 can be mounted, and the evaporator 800 are installed A groove provided to allow the second blowing unit 700 to be installed may be formed spaced apart from the upper side of the partition plate 600 .

The refrigerant flowing between the condenser 500, the compressor 202, and the evaporator 800 is flowed by the refrigerant pipe 400 made of a pipe, and this refrigerant pipe 400 passes through the pipe passage hole 624. It can be installed vertically through

Meanwhile, fastening grooves or fastening protrusions for fastening with the case may be formed near the ends of the left and right side surfaces of the partition plate 600 .

An evaporator 800 may be installed on the upper surface of the partition plate 600 . The evaporator 800 may include a second refrigerant pipe 810 through which refrigerant may flow and a second heat dissipation plate 820 .

As shown, the evaporator 800 may be installed on the left and right sides of the upper surface of the partition plate 600 . The installation directions of the evaporators 800 installed in the left and right directions in the second accommodation space and the condenser 500 installed in the front and rear directions in the first accommodation space may cross each other.

This is to efficiently arrange the devices installed inside the accommodation space by installing the indoor heat exchanger and the outdoor heat exchanger crosswise.

When the evaporator 800 is installed in the left and right sides, the air introduced through the second inlet 1110 disposed at the rear passes through the evaporator 800 to the rear, and then the direction is changed by the second blowing unit 700, and the direction is changed to the front can be emitted as

The evaporator 800 may serve as an evaporator. The refrigerant flowing inside the second refrigerant pipe 810 and the air passing between the second heat dissipation plate 820 perform heat exchange. The refrigerant absorbs heat from the air to change its phase into a gas, and the air absorbs heat from the refrigerant to lower its temperature.

That is, when the mobile air conditioner 10 is driven as a cooler, air introduced into the second accommodation space through the second suction grill 1120 formed on the upper part of the rear case 1100 passes through the evaporator 800. While doing so, it exchanges heat with the refrigerant flowing inside the evaporator 800. Then, the air cooled while passing through the evaporator 800 is discharged into the room through the outlet 1044 .

The air introduced into the mobile air conditioner 10 and discharged into the room may be forcibly flowed by the second blowing unit 700 installed as a part of the mobile air conditioner 10 .

Although various types of blowers may be used as the second blower unit 700, as shown, a centrifugal blower may be used.

A centrifugal blower is a blower that generates air volume and pressure while moving air in the radial direction of the impeller, and can flow a large volume of air at a low pressure. In addition, since the diameter of the impeller can be formed small, the installation space can be minimized, and thus the mobile air conditioner 10 can be miniaturized.

A second blowing unit 700 may be installed on the upper surface of the partition plate 600 . The second blowing unit 700 includes a second blowing housing 720 provided with a second blowing guide 721 and a second blowing orifice 722, a second blowing motor 730, and a second impeller 740. It can be.

A second blowing orifice 722 may be disposed adjacent to the evaporator 800 on one side of the evaporator 800 . The second blowing orifice 722 guides the air passing through the evaporator 800 into the second blowing housing 720 .

The air introduced into the second blower housing 720 rotates along the second centrifugal passage 723 formed inside the second blower housing 720 and passes through the second blower 725 to the outside of the second blower unit 700. can be emitted as

A second impeller 740 for forcing the flow of air is installed inside the second blower housing 720 . The second impeller 740 rotates by the second blower motor 730 and forces air flow.

Air introduced into the second blowing unit 700 by the rotation of the second blowing motor 730 may be discharged into the room through the discharge port 1044 communicating with the second air outlet 725 .

8 is a perspective view showing a base plate of a mobile air conditioner according to an embodiment of the present invention, FIG. 9 is a view showing a state in which a splash fan is installed on the base plate 100 of FIG. 8, and FIGS. 10 and 11 are It is a perspective view and a side view of the splash impeller 112 constituting the splash fan 110 of FIG. 9 .

As shown, the base plate 100 may have a substantially rectangular shape corresponding to the shape of the cross section of the bottom portion of the accommodation space.

On the upper surface of the base plate 100, a plurality of first bottom partitioning ribs 102 are formed. The first floor partitioning rib 102 is to form a space in which condensate can flow by allowing a plurality of seals to be formed on the upper surface of the base plate 100 .

Looking more specifically, a plurality of first bottom partitioning ribs 102 are formed on the upper surface of the base plate 100, and condensate water flowing into the upper surface of the base plate 100 is formed at one end of the base plate 100. (130) can be made to flow.

The first floor partitioning rib 102 is integrally formed with the base plate 100 and may protrude upward from the upper surface of the base plate 100 .

In addition, the first bottom partition rib 102 is generated in the evaporator 500 by preventing a plurality of parts such as the condenser 500 installed on the top of the base plate 100 from being in close contact with the upper surface of the base plate 100 Thus, a predetermined space is formed so that the condensed water that has fallen can easily flow on the upper surface of the base plate 100 .

A condensed water storage unit 104 may be provided on the upper surface of the base plate 100 and is recessed downward.

The refrigerant condensed in the condenser 500 may flow and be evaporated inside the evaporator 800 . When the refrigerant is evaporated, vaporization heat is absorbed by the second refrigerant pipe 810 and the second heat dissipation plate 820 constituting the evaporator 800 . The temperature of the evaporator 800 that absorbs the heat of vaporization decreases. Since heat moves from the air passing through the evaporator 800 to the evaporator 800, the temperature of the air passing through the evaporator 800 decreases and condensed water is generated.

The condensed water generated in the evaporator 800 flows downward due to its own weight, and may flow from the second accommodating space to the first accommodating space through the partition plate 600 . The upper surface of the base plate 100 may be formed concave to collect and process the condensed water flowing downward into the condensed water storage unit 104 .

The condensed water collected in the condensed water storage unit 104 may be discharged to the outside through the condensed water outlet 130 provided at the side end of the base plate 100 .

The condensate water reservoir 104 and the condensate outlet 130 are connected to the upper surface of the base plate 100 so that the condensate collected in the condensate water reservoir 104 flows through the upper surface of the base plate 100 and flows into the condensate outlet 130. A condensate flow path 106 may be formed so as to be formed.

The condensate passage 106 may be concavely formed on the upper surface of the base plate 100 or formed by the first bottom partition rib 102 .

The base plate 100 may be formed such that the condensate passage 106 is inclined so that the condensed water flows from the condensate water reservoir 104 to the condensate outlet 130 .

As shown, a splash fan 110 composed of a splash impeller 112 and a splash motor 118 may be provided on one side of the condensed water passage 106 formed on the upper surface of the base plate 100.

The splash impeller 112 may be rotationally driven by a splash motor 118 having a rotating shaft connected to the center of the splash fan 110 . The splash impeller 112 rotates and the condensate flowing along the condensate flow path 106 may be sprayed toward the condenser 500 .

The refrigerant discharged from the compressor 202 at high temperature and high pressure may flow and be condensed inside the condenser 500 . When the refrigerant is condensed, liquefaction heat is released to the first refrigerant pipe 510 and the first heat dissipation plate 52 constituting the condenser 500 . The temperature of the condenser 500 subjected to liquefaction heat is lowered. Since heat moves from the condenser 500 to the air passing through the condenser 500, the temperature of the air passing through the condenser 500 rises. Air whose temperature has increased by passing through the condenser 500 may be discharged to the outdoors through an exhaust port.

For efficient condensation of the refrigerant in the condenser 500, the first blowing unit 300 is disposed on the side of the condenser 500.

If there is liquid on the surface of the condenser 500, the liquid on the surface of the condenser 500 can absorb vaporization heat on the surface of the condenser 500, so that the refrigerant can be more actively condensed.

The splash fan 110 is provided to spray condensed water toward the condenser 500 so that liquid is formed on the surface of the condenser 500 .

As illustrated, the splash impeller 112 includes an impeller disk 113 and an impeller rotating shaft 114 so that the condensate flowing along the condensate flow path 106 by the splash fan 110 can be efficiently sprayed toward the condenser 500. ) and side wings 115.

The impeller disk 113 may be provided as a circular plate. This is to facilitate rotation of the splash impeller 112 on the condensate flow path 106 side.

An impeller rotation shaft 114 that can be coupled with the rotation shaft of the splash motor 118 is provided at the center of the side surface of the impeller disk 113 .

The side blades 115 protrude from the side of the impeller disk 113 so that the condensate flowing along the condensate flow path 106 is sprayed toward the condenser 500.

As shown, the side blades 115 are preferably arranged radially around the impeller shaft 114 so that the injection of condensed water is efficiently performed.

This is to enable the side blades 115 to pump the condensed water flowing along the condensed water passage 106 upward, so that the condensed water is efficiently injected toward the condenser 500.

The side blades 115 are preferably made of a curved shape protruding in the opposite direction of the rotational direction of the splash impeller 112.

When the side blades 115 are curved in the opposite direction to the direction of rotation of the splash impeller 112, the angle of entry between the side blades 115 and the condensate surface can be reduced to reduce the resistance acting on the side blades 115. . In addition, a large amount of condensed water can be pumped by the side blades 115. In addition, the condensed water pumped by the side blades 115 can be efficiently sprayed upward.

The splash impeller 112 may further include a positive part 117 penetrating the impeller disk 113 adjacent to the side blade 115 and in front of the side blade 115 based on the rotation direction. The pumping part 117 may be provided as a groove on the side of the impeller disk 113 or may be provided as a hole penetrating the side of the impeller disk 113 . The pumping unit 117 can spray a large amount of condensed water to the condenser 500 along with the side blades 115.

The splash impeller 112 may include circumferential blades 116 protruding in the circumferential direction on the circumferential surface of the impeller disk 113. The circumferential blade 116 protrudes from the circumferential surface so that the condensed water on the circumferential surface side is sprayed in the rotational direction.

The circumferential blades 116 may be formed on the circumferential surface of the impeller disk 113 so as to be inclined in the direction of rotation of the splash impeller 112. This is to reduce the inlet angle formed by the circumferential blade 116 and the condensate surface, and to efficiently spray the condensate upward.

12 is a perspective view showing a state in which the condenser is installed on the base plate of FIG. 9, FIG. 13 is a plan view of FIG. 12, and FIG. 14 is condensed water into the condenser by the splash fan of the mobile air conditioner according to an embodiment of the present invention. It is a conceptual diagram showing the state of supply.

As shown, the condenser 500 of the mobile air conditioner according to an embodiment of the present invention may include a first condensing unit 550 and a second condensing unit 560. The first condensing unit 550 and the second condensing unit 560 have the first refrigerant pipe 510 connected to one so that the refrigerant can be circulated, but the first heat dissipation plate 52 can be divided into two areas. can do.

This is to expand the surface area of the condenser 500 and, as shown, allow the splash fan 110 to be disposed between the condenser 500, so that condensed water can be sprayed between the condenser 500.

15 is a conceptual diagram illustrating an installation state of a condenser and a splash fan of a mobile air conditioner according to an embodiment of the present invention, and FIG. 16 is a conceptual diagram illustrating another embodiment of FIG. 13 .

As shown, the condenser 500 is disposed on the side of the condensate water reservoir 104 or the condensate flow path 106, and the splash impeller 112 is provided between the first condensing unit 550 and the second condensing unit 560. It can be installed so that it can be formed.

The first condensing unit 550 and the second condensing unit 560 are spaced apart and disposed side by side, and the splash impeller 112 is formed between the spaced first condensing unit 550 and the second condensation unit 560. can

If the separation distance between the first condensing unit 550 and the second condensing unit 560 is too close, the condensed water may not be concentrated and sprayed at the lower end of the condenser 500 because a space in which the condensed water can sufficiently reach the upper side is not formed. can On the other hand, when the separation distance between the first condensing unit 550 and the second condensing unit 560 is too long, condensed water may be concentrated on the upper end of the condenser 500 .

Therefore, it is preferable that the separation distance between the first condensing unit 550 and the second condensing unit 560 is 14 mm to 20 mm.

This is to provide a space in which the splash impeller 112 can be formed between the first condensing unit 550 and the second condensing unit 560 . It is preferable to maintain a distance of 3 mm to 5 mm between both sides of the splash impeller 112 and the first and second condensing units 550 and 560, respectively. This is to provide a space where the condensed water sprayed upward by the rotation of the splash impeller 112 can reach the lower and upper sides of the condenser 500 evenly.

In the condenser 500, the heights of the lower ends of the first condensing unit 550 and the second condensing unit 560 are preferably formed to be different.

In the splash impeller 112, the impeller rotation shaft 114 formed in the center of the side surface is coupled to the rotation shaft of the splash motor 118. Since the separation distance between the first condensing unit 550 and the second condensing unit 560 is narrow for the splash motor 118 to be installed, the splash motor 118 is disposed outside the condenser 500 and the first condensing unit 550 is disposed outside the condenser 500. This is so that the lower end of the portion 550 is located above the portion where the rotation shaft of the impeller rotation shaft 114 and the rotation shaft of the splash motor 118 are coupled.

At this time, it is preferable that the distance between the lower end of the second condensing unit 560 and the upper surface of the condensing water storage unit 104 is formed within 30 mm. Of course, the lower end of the second condensing unit 560 may contact the upper surface of the base plate 100 . Then, the lower end of the second condensing unit 560 may be disposed to be submerged in the condensed water.

When the lower end of the second condensing unit 560 is submerged in condensed water, the condenser 500 can be easily cooled because heat is directly transferred to the condensed water.

17 is a conceptual diagram showing a state in which air flows inside the mobile air conditioner 10 according to an embodiment of the present invention.

Hereinafter, with reference to FIG. 21, the operation of the mobile air conditioner 10 according to the present invention as described above will be described.

First, the flow of refrigerant and air in the mobile air conditioner 10 according to the present invention will be examined.

The mobile air conditioner 10 according to the present invention can be used for cooling or heating, but as described above, a case in which the mobile air conditioner 10 according to the present invention is used for cooling will be described as an example.

At this time, the condenser 500 serves as a condenser and the evaporator 800 serves as an evaporator. A refrigerant pipe 400 is connected between the compressor 202, the condenser 500, and the evaporator 800 to guide the flow of the refrigerant.

Therefore, when the gaseous refrigerant is compressed from the compressor 202 and becomes a high-temperature, high-pressure state and flows into the condenser 500, the refrigerant is condensed in the condenser 500 by heat exchange with outside air.

Then, the condensed refrigerant is expanded while passing through an expansion valve (not shown) and introduced into the evaporator 800 .

The refrigerant introduced into the evaporator 800 evaporates through heat exchange with external air. Therefore, the refrigerant is in a gaseous state, but at this time, the refrigerant in a liquid state also remains, so that the two-phase refrigerant actually coexists.

After passing through the accumulator 203, the refrigerant flows back to the compressor 202 to complete a refrigerant cycle.

Meanwhile, air exchanges heat while passing through the condenser 500 and the evaporator 800 .

First, air flow (indicated by a black arrow in the drawing) in the heat radiation side (first accommodating space) will be examined. Air flow at this time is basically generated by the first impeller 340 .

That is, when the first blower motor 330 is driven by power applied from the outside, the first impeller 340 connected to the shaft of the first blower motor 330 rotates to generate air flow. will be.

Accordingly, air from the rear may be introduced through the first inlet 1130 formed at the bottom of the rear case 1100 . The air introduced through the first inlet 1130 changes direction to flow sideways and passes through the condenser 500 .

The temperature of the air passing through the condenser 500 rises. That is, since the condenser 500 serves as a condenser, heat is transferred from the refrigerant flowing inside the condenser 500 and the air becomes a high temperature state.

The high-temperature air passing through the condenser 500 passes through the first blowing orifice 323 and is introduced into the central portion of the first impeller 340 . The air introduced into the central part of the first impeller 340 flows radially by the rotation of the first impeller 340 and is guided inside the first blowing guide 322 and the first blowing orifice 323 and discharged upward.

The high-temperature air guided inside the first blowing guide 322 and the first blowing orifice 323 and discharged upward is completely discharged to the outside of the building through the pipe part 1300 .

Next, a flow of air (indicated by a white arrow in the drawing) occurring in the heat absorbing side (second receiving space) will be examined. Air flow at this time is basically generated by the second impeller 740 .

That is, when the second blower motor 730 is driven by power applied from the outside, the second impeller 740 connected to the shaft of the second blower motor 730 rotates to generate air flow. will be.

Therefore, outside air is introduced into the first accommodation space through the second inlet 1110 formed on the upper part of the rear case 1100 . The air introduced through the second intake port 1110 passes through the second intake grill 1120 and a filter installed on the side of the second intake port 1110, and in this process, foreign substances or odors in the air can be removed.

The air introduced into the second accommodating space passes through the evaporator 800, and heat exchange occurs in this process. That is, since the evaporator 800 acts as an evaporator, the air passing through the evaporator 800 is cooled by heat exchange with the refrigerant.

The low-temperature air that has passed through the evaporator 800 flows through the second blowing orifice 722 and is introduced into the center of the second impeller 740 . The air introduced into the center of the second impeller 740 is radially discharged by the rotation of the second impeller 740, and this air is guided inside the second blowing guide 721 and the second blowing orifice 722 to the upper side. will flow with

The air guided inside the second blowing guide 721 and the second blowing orifice 722 and flowing upward passes through the second outlet 725 and the discharge louver 750 . The low-temperature air passing through the discharge louver 750 can be diverted and discharged, so that the indoor space can be smoothly cooled.

Next, condensate flow is examined.

In the evaporator 800, heat exchange occurs between external air and internal refrigerant, and in this process, moisture in the air is condensed to generate condensed water.

The condensed water generated in this process comes down to the bottom of the evaporator 800 and falls on the upper surface of the partition plate 600 . Condensate falling on the upper surface of the partition plate 600 is guided by the second bottom partition rib 602 and flows, and in this process moves downward through the partition plate 600 through the condensate drop hole 604. do.

The condensate passing through the condensate drop hole 604 and moving to the lower side of the partition plate 600 wets the condenser 500 and cools down, and then falls downward.

The condensed water that has fallen downward may flow into the upper surface of the base plate 100 . The condensed water flowing into the upper surface of the base plate 100 may flow toward the condensate outlet 130 provided at one end of the base plate 100 along the condensed water passage 106 formed on the upper surface of the base plate 100.

When the condensate flows toward the condensate outlet 130, it may be discharged to the outside of the mobile air conditioner 10 through the condensate outlet 130.

What has been described above is only the embodiments for carrying out the present invention, the present invention is not limited to the above embodiments, and as claimed in the claims below, within the scope that does not depart from the gist of the present invention Anyone with ordinary knowledge in the field to which the invention belongs will say that the technical spirit of the present invention exists to the extent that various changes can be made.

10: mobile air conditioner 100: base plate
102: first bottom partition rib 104: condensate water reservoir
106: condensate oil 110: splash fan
112: splash impeller 113: impeller disk
114: impeller axis of rotation 115: side wing
116: circumferential wing 117: amniotic fluid
118: splash motor 130: condensate outlet
150: moving wheel 200: compression unit
202: compressor 203: accumulator
204: compressor frame 300: first blowing unit
310: first ventilation grill 322: first ventilation guide
322: first blowing orifice 324: first blowing port
330: first blowing motor 340: first impeller
400: refrigerant pipe 500: condenser
510: first refrigerant pipe 520: first heat dissipation plate
550: first condensation unit 560: second condensation unit
600: partition plate 601: water storage groove
602: second bottom partition rib
604: condensate drop hole 604a: inlet rib
604b: exit rib 604c: exit groove
605: condensate drain hole 605a: inlet rib
605b: exit rib 605c: exit groove
620: control box mounting hole
624: pipe passage hole 700: second blower unit
710: second blower grill 720: second blower housing
721: second blowing guide 722: second blowing orifice
723: second centrifugal flow path 724: second blower
725: second air outlet 726: air outlet
727: blowing nozzle hole 730: second blowing motor
740: second impeller 750: discharge louver
751: discharge cover 752: discharge rib
753: vertical discharge rib 754: horizontal discharge rib
756: Live Euro 758: Louver Rotation Axis
760: louver installation groove 770: louver motor
800: evaporator 810: second refrigerant pipe
820: second heat dissipation plate 900: control box
950: support angle 1000: front case
1020: control unit 1040: discharge frame
1041: discharge part 1044: discharge port
1050: discharge flow path 1100: rear case
1110: second suction port 1120: second suction grill
1122: second suction filter frame 1124: second suction filter
1130: first suction port 1140: first suction grill
1142: first suction filter frame 1144: first suction filter
1170: installation kit storage unit 1180: exhaust port
1200: installation kit 1300: piping
1310: piping pipe 1320: piping nozzle
1330: pipe connector 1340: pipe grill

Claims (8)

case forming the exterior;
a base plate coupled to the lower portion of the case;
a condenser disposed on the base plate;
a first blowing unit disposed adjacent to the condenser;
a partition plate partitioning a space in which the condenser and the first blowing unit are disposed;
an evaporator disposed above the partition plate;
a second blowing unit disposed adjacent to the evaporator;
a water storage groove provided on the partition plate to provide a space in which the condensed water that has been condensed and dropped from the evaporator is stored;
a condensate drop hole disposed inside the water storage groove to allow the condensed water stored in the water storage groove to pass through the partition plate and fall; and
a condensate drain hole disposed inside the water storage groove and having a larger diameter than the condensate drop hole;
including,
A mobile air conditioner having a diameter corresponding to the diameter of the refrigerant pipe of the condenser.
According to claim 1,
The condensate falling hole is a mobile air conditioner arranged to overlap with the condenser directly above the condenser.
According to claim 2,
The condensate drop hole is a mobile air conditioner arranged to overlap with the refrigerant pipe of the condenser.
According to claim 1,
The condensate falling hole is a mobile air conditioner having an inlet rib protruding upward from the water storage groove.
According to claim 1,
The condensate falling hole is a mobile air conditioner having an outlet rib protruding from the bottom of the water storage groove.
delete According to claim 1,
The condensate falling hole has an inlet rib protruding upward from the water storage groove,
The condensate drain hole has an inlet rib protruding upward from the water storage groove,
A mobile air conditioner in which the inlet rib of the condensate drain hole protrudes higher than the inlet rib of the condensate drop hole.
In paragraph 5,
A mobile air conditioner having an outlet groove formed around an outlet rib of the condensate falling hole at a lower portion of the water storage groove.

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