KR20190083888A - Movable air conditioner - Google Patents

Abstract

The present invention relates to a movable air conditioner and, more particularly, to a movable air conditioner that operates to achieve rapid discharge of condensate. To this end, the movable air conditioner comprises: a case having a suction port, an exhaust port, and a discharge portion; a base plate coupled to the bottom portion of the case; a receiving space defined by the case and the base plate; a first heat exchanger installed in the receiving space; a first blowing unit installed adjacent to the first heat exchanger inside the receiving space; and a condensate discharge module installed adjacent to the first blowing unit, wherein the condensate discharge module includes a water level sensor configured to sense different first and second water levels of the condensate collected in the base plate.

Description

{MOVABLE AIR CONDITIONER}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a portable air conditioner, and more particularly, to a portable air conditioner that operates to rapidly discharge condensed water.

Generally, a portable air conditioner has a configuration in which components such as a compressor, an evaporator (generally an indoor exchanger), an expansion valve, and a condenser (generally, an outdoor heat exchanger) are integrally contained in a single product.

The portable air conditioner is simpler in installation than a general air conditioner in which an outdoor unit is separately provided, so that a consumer can install the unit himself or herself and has an advantage of being easy to install.

The portable air conditioner can be freely installed in a room adjacent to a window in an indoor space such as a mall, an office or a home.

The portable air conditioner generally performs only the cooling function for cooling the room air, but it is also possible to perform the reverse circulation of the refrigerant so that the cooling cycle and the heating cycle are switched.

2. Description of the Related Art In recent years, a mobile air conditioner having a configuration in which a moving wheel is attached to a floor and a user can easily move has been actively developed and popularized.

The movable type air conditioner is installed in a state where the condenser and the evaporator are separated in a space partitioned inside a single device, so that the movable type air conditioner can be miniaturized and moved. In addition, the air discharged from the building to the outside through the heat exchange with the refrigerant can be installed in the window frame using a separate installation duct.

Since the portable air conditioner is easy to move and install, the user can easily place the portable air conditioner in a desired place without the help of a specialist who has acquired a separate technique for installation.

It is possible to move the portable air conditioner to achieve air conditioning at a desired place, and it is possible to save installation cost since the user does not have to install the air conditioner separately for the installation and can easily install the air conditioner.

However, since the portable air conditioner is not installed on a wall or ceiling but can be used in a state of being mounted on a floor, a discharge port through which the air-conditioned air is discharged into the room is formed on the upper portion of the portable air conditioner It is common. According to such a feature of the mobile type air conditioner, the discharge flow path can be formed in the vertical direction.

During operation of the portable air conditioner, water (hereinafter referred to as condensate) may be generated in the condenser and the evaporator due to condensation or the like. The condensed water generated in the evaporator is collected by the partition plate which divides the interior space into upper and lower parts, and is moved to the base plate, and the condensed water generated in the condenser is immediately collected in the base plate.

At this time, the condensate drain module senses the level of the condensate collected in the base plate of the portable air conditioner, and discharges the condensate when a predetermined amount of condensed water is sensed. As a device for discharging such condensed water, a water level sensor or a drain pump may be used.

However, when a separate condensate drain module is installed inside the mobile air conditioner for sensing the level of the condensed water and discharging the condensed water, not only the manufacturing cost increases, but also a problem that it is difficult to secure an installation space inside.

In addition, the drain pump not only inconveniences the user during operation, but also consumes a relatively large amount of electric power. Therefore, the problem of decreasing the total energy efficiency of the mobile air conditioner when continuously operating at a certain level or more there was.

It is an object of the present invention to provide a portable air conditioner which can simplify the structure of the condensate drainage module and reduce the number of assembling air and the installation cost by assembling the water level sensor and the drain pump to the air flow guide of the condenser.

It is another object of the present invention to minimize the operation noise of the drain pump by minimizing the operation of the components of the portable air conditioner according to the level of the condensed water collected at the lower portion of the portable air conditioner, And to provide a portable air conditioner capable of improving energy efficiency.

According to an aspect of the present invention, there is provided an air conditioner comprising: a case having a suction port, an air outlet and a discharge portion; a base plate coupled to a lower portion of the case; A first blowing unit installed adjacent to the first heat exchanger inside the accommodation space, and a condensate drain module installed adjacent to the first blowing unit. At this time, the condensate drainage module provides a mobile air conditioner including a water level sensor for sensing different first and second water levels of condensed water collected in the base plate.

The condensate drainage module further includes a drainage pump for discharging the condensed water to the outside through a drain pipe, and a drainage module frame formed integrally with the airflow guide of the first blowing unit and fixing the level sensor and the drainage pump.

The water level sensor includes a first water level sensor for sensing the first water level and a second water level sensor for sensing the second water level, and the first and second water level sensors are installed to have steps in the drain module frame.

According to another aspect of the present invention, there is provided an air conditioner comprising: a case having an inlet, an air outlet and a discharge portion; a base plate coupled to a lower portion of the case; A water level sensor for sensing the level of the condensed water collected in the base plate, and a drain for discharging the condensed water to the outside through the drain pipe, A condensate drain module including a pump, a splash fan provided on a flow path formed on the upper surface of the base plate, and a control box for controlling operations of the first heat exchanger, the first blower unit, the condensate drain module, and the splash fan . At this time, if the level of the condensed water sensed by the water level sensor is higher than the first water level and lower than the second water level, the control box may drive the splash fan or change the operation speed of the first blowing unit, When the water level is higher than the water level, a mobile air conditioner for driving a drain pump is provided.

When the level of the condensed water sensed by the water level sensor is higher than the first water level and lower than the second water level, the control box controls the first heat exchanger to cool the first heat exchanger, The operation of the compressor is controlled so that the temperature of the refrigerant supplied is raised.

The movable type air conditioner according to the present invention can reduce the number of parts and reduce the number of assembly parts of the condensate drainage module by assembling the water level sensor and the drain pump in the drainage module frame integrally formed with the airflow guide of the condenser. In addition, the present invention can reduce the manufacturing cost required to manufacture the condensate drainage module and simplify the structure, thereby reducing the failure rate of the condensate drainage module.

Also, the mobile air conditioner according to the present invention senses the level of the condensed water generated in the operation of the portable air conditioner in two stages, and changes the operation mode of the portable air conditioner according to the level, . Accordingly, the portable air conditioner can control the components in different ways according to the level sensed by the condensate drainage module, thereby quickly discharging the condensed water to the outside. By minimizing the operation of the drainage pump, the use of the portable air conditioner Energy efficiency can be improved by optimizing the amount of power.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a front perspective view showing an appearance of a preferred embodiment of a portable air conditioner according to the present invention; FIG.
2 is a rear perspective view showing an appearance of a preferred embodiment of the mobile type air conditioner according to the present invention.
FIG. 3 is a view showing a state in which the installation kit and the piping unit are installed in FIG. 2;
4 is an exploded perspective view showing the internal structure of the mobile air conditioner according to the embodiment of the present invention.
5 is a perspective view of a base plate on which components are installed in the mobile type air conditioner according to the embodiment of the present invention.
6 is a perspective view of a partition plate on which components are installed in the mobile type air conditioner according to the embodiment of the present invention.
7 is a perspective view illustrating a partition plate of a portable air conditioner according to an embodiment of the present invention.
8 is a perspective view of a base plate of a mobile air conditioner according to an embodiment of the present invention.
9 is a view showing a condensate drainage module of a mobile air conditioner according to an embodiment of the present invention.
Figs. 10 and 11 are a partial perspective view and a partial cross-sectional view showing an enlarged S region of Fig.
12 is a partial cross-sectional view showing a cross-section viewed from the AA line in FIG.
13 is a partial cross-sectional view showing a section taken along the line BB in Fig.
14 and 15 are views for explaining the operation of the drain pump of the mobile type air conditioner according to the embodiment of the present invention.
16 to 18 are views for explaining the operation of the mobile type air conditioner and the flow of air according to the embodiment of the present invention.
19 and 20 are views for explaining another embodiment of the water level sensor included in the mobile type air conditioner according to the embodiment of the present invention.

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

As used herein, the singular forms "a", "an" and "the" include plural referents unless the context clearly dictates otherwise.

In the following description of the embodiments of the present invention, a detailed description of related arts will be omitted when it is determined that the gist of the embodiments disclosed herein may be obscured.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. It should be understood that it includes water and alternatives.

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

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

The case may be made up of one case forming an outer front and rear side, but it may include a front case 1000 forming a front side outer tube so as to facilitate assembly and disassembly of the product, a front case 1000 forming a rear side case, (1100).

A bottom surface of the front and rear cases 1000 and 1100 is formed and a base plate 100 supporting parts installed inside the front and rear cases 1000 and 1100 can be coupled to the lower parts of the front and rear cases 1000 and 1100. [ (The front can be defined with reference to the direction toward the user when the portable air conditioner 10 is disposed).

In general, the portable type air conditioner 10 is configured to allow the refrigerant to flow inside the movable type air conditioner 10 and to perform heat exchange twice with surrounding air. The first and second heat exchangers (500, 800) are provided in the receiving space of the mobile type air conditioner (10) so that the refrigerant and the surrounding air can exchange heat. And the first and second heat exchangers (500, 800) are installed in the respective accommodating spaces, the mobile air conditioner (10) can be made compact and movable.

Accordingly, the receiving space defined by the front and rear cases 1000, 1100 and the base plate 100 can be partitioned by the partition plate 600 into a second accommodating space on the upper side and a first accommodating space on the lower side.

The second heat exchanger 800 and the second blower unit 700 adjacent thereto are installed in the second accommodation space and the second heat exchanger 800 and the second blower unit 700 are mounted on the partition plate 600 .

The first heat exchanger 500 and the first blower unit 300 adjacent to the first heat exchanger 500 are installed in the first housing space. The first heat exchanger 500 and the first blower unit 300 are connected to the base plate 100, As shown in FIG. The upper surfaces of the first heat exchanger 500 and the first blower unit 300 mounted on the base plate 100 support the bottom surface of the partition plate 600 to improve the structural stability.

In the cases 1000 and 1100, there may be formed an intake port through which outside air can be introduced into the housing space, and an exhaust port 1180 and a discharge section 1041 through which the air inside the accommodation space can be discharged to the outside. The suction port may include a second suction port 1110 communicating with the second accommodating space and a first suction port 1130 communicating with the first accommodating space.

Condensation and evaporation of the refrigerant are separated in the upper and lower receiving spaces and heat exchange can occur. For example, the first heat exchanger 500 may operate as a condenser and the second heat exchanger 800 may be configured to operate 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 350 so that the refrigerant can flow.

In this way, the movable type air conditioner 10, which is constituted integrally with a single product such as an evaporator, a condenser, a compressor and the like, can be made compact, which is advantageous in that it can be easily installed and moved.

1 and 2, the movable type air conditioner 10 according to the present invention includes a front case 1000 forming an outer appearance on the front side and a rear case 1100 forming an outer appearance on the rear side The overall appearance can be schematically formed.

The front case 1000 can form the skeleton of the front part, and can partially form the appearance of the upper surface and the right and left side surfaces.

The rear case 1100 may be provided to partly form the appearance of the upper surface and the right and left side surfaces as well as the rear side appearance of the movable type air conditioner 10 according to the present invention.

The rear case 1100 may be connected to a piping unit 1300 for discharging the heat-exchanged air to the outside (outside the building). The piping portion 1300 may be installed so as to communicate with the second accommodation space or the first accommodation space defined by the upper and lower portions, and the piping portion 1300 may be installed so as to communicate with the accommodation space provided with the heat exchanger functioning as the condenser.

In the case where the portable air conditioner 10 operates for cooling, the refrigerant in the high temperature and high pressure state, which has passed through the compressor 202, and the air in which the temperature is increased in the condenser, The pipe 1300 is installed so as to communicate with a receiving space provided with a heat exchanger functioning as a condenser.

Hereinafter, the first heat exchanger 500 installed in the first accommodation space will be described as a condenser, so that the mobile air conditioner 10 is driven by 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 tube and guides the flow of the exhaust gas. The piping nozzle 1320 is an end for guiding the exhaust gas flowing through the exhaust pipe to be finally discharged.

The pipe pipe 1310 is preferably made of a flexible material or a shape so as to be capable of bending.

The piping connector 1330 is provided between the rear case 1100 and the piping pipe 1310 so that one end of the piping pipe 1310 is guided to be mounted on the rear case 1100.

An exhaust port 1180 through which the air in the first accommodation space can be discharged may be formed under the rear case 1100. One end of the pipe pipe 1310 may be connected to the exhaust port 1180 by a pipe connector 1330 have.

The piping unit 1300 is for discharging the heat-exchanged air to the outside of the receiving space. The piping unit 1300 is connected to the rear case 1100 at one end and exposed to the outside at the other end.

The other end of the pipe portion 1300 can be easily exposed to the outside through the window frame. This is because the window is formed so as to communicate the indoor and the outdoor and is easily opened and closed.

That is, the window is opened by the diameter of the other end of the pipe portion 1300, and the other end of the pipe portion 1300 is exposed to the outside through the window open gap. This is because the other end of the pipe portion 1300 can be exposed outdoors without puncturing the wall.

The installation kit 1200 is required to fix the other end of the pipe portion 1300 to the window frame and seal the window gap when the other end of the pipe portion 1300 is mounted on the window frame.

The installation kit 1200 is a device for fixing the other end of the pipe portion 1300 so as to prevent the other end of the pipe portion 1300 from moving while blocking a gap of the window corresponding to the diameter of the pipe portion 1300.

Accordingly, the installation kit 1200 may have a rectangular shape corresponding to the shape of the window gap, and may have a through-hole through which the other end of the pipe portion 1300 can be inserted.

It is preferable that the installation kit 1200 is provided so that a plurality of plates can be slidably coupled to each other to adjust the length thereof so as to facilitate storage and transportation.

The piping 1300 and the installation kit 1200 constituting the portable air conditioner 10 can be operated separately from the mobile air conditioner 10 as components constituting the outside of the mobile air conditioner 10. [

The piping section 1300 and the installation kit 1200 are installed in the rear case 1100 to facilitate the storage and movement of the piping section 1300 and the installation kit 1200 when the portable air conditioner 10 is stored and moved. As shown in FIG.

The mounting kit 1200 may be inserted into the mounting kit accommodating portion 1170 formed in the rear case 1100 so that the moving type air conditioner 10 and the mounting kit 1200 may be integrally mounted. have.

Fig. 4 is an exploded perspective view of the structure of the mobile air conditioner 10 according to the present invention. 5 is a perspective view of the base plate 100 on which the components are installed, and FIG. 6 is a perspective view of the partition plate 600 on which the components are installed.

As shown in the figure, the front case 1000 may be provided such that the center portion thereof protrudes relatively forward to enhance the appearance quality. Therefore, the front case 1000 can be formed so as to have an overall rounded curvature when viewed from the side.

This is to improve appearance quality by configuring the appearance of the portable air conditioner 10 in a round shape.

A discharging portion 1041 may be formed at an upper portion of the case.

The discharge portion 1041 is provided with a discharge port 1044 penetrating through the discharge portion 1041 so that the inside of the case can communicate with the outside when the discharge portion 1041 is provided in the case. The discharge port 1044 is communicated with the second blowing port 725 to be described below, and the discharge port 1044 is formed long to the left and right to form a rectangular shape and can smoothly discharge air into the room.

The discharge portion 1041 is formed in a separate discharge frame 1040 and the discharge portion 1040 is mounted on the upper portion of the case so that the discharge portion 1041 can be provided on the upper portion of the case. Alternatively, the discharging portion 1041 may not be formed in a separate discharging frame 1040, but may be provided integrally with the case.

Whether the discharging portion 1041 is formed as a separate frame or integrally formed with the case, the discharging portion 1041 is a portion through which the air-conditioned air is discharged in the receiving space and is formed on the upper portion of the mobile air conditioner 10 desirable. This takes into account the fact that the normally movable mobile air conditioner 10 is disposed at the floor in the room.

The discharge port 1044 is provided at the upper end of the case so that the air-conditioned air is discharged to the upper portion and the air-conditioned air is discharged to the front side of the mobile-type air conditioner 10. A discharge louver 750 may be additionally provided.

An operation unit 1020 may be provided on the upper portion of the case. In order to facilitate the operation of the mobile air conditioner 10 disposed on the floor, the operation unit 1020 is preferably disposed on the upper portion of the mobile air conditioner 10.

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

The operation unit 1020 may be installed directly on the case, but may be mounted on a case as a module mounted on a separate case capable of accommodating the operation unit 1020.

Considering that the discharging portion 1041 and the operating unit 1020 are disposed above the mobile air conditioner 10, the discharging portion 1041 and the operating unit 1020 can be mounted on the upper portion of the case As shown in FIG.

The rear case 1100 can be coupled to the front case 1000. The front end of the rear case 1100 may be formed in a shape corresponding to the front case 1000 in consideration of the fact that the rear case 1100 and the front case 1000 are coupled.

That is, when the rear ends of the left and right side surfaces of the front case 1000 are rounded or inclined, the left and right side end portions of the rear case 1100 are curved in a rounded shape corresponding to the left and right side rear ends of the front case 1000 Or may be formed obliquely.

A second suction port 1110 may be formed in the upper portion of the rear case 1100 to pass through the inside and the outside of the second accommodating space. The second suction port 1110 is a passage through which the air in the room is sucked into the second accommodation space.

The second suction port 1110 may be formed in a variety of shapes, but it is preferably formed in a square shape to secure a sufficient area of the second suction port 1110.

The second suction port 1110 may further include a second suction filter frame 1122 so that the second suction filter 1124 can be supported.

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

The second suction grille 1120 is preferably formed to have a size corresponding to that of the second suction port 1110 so as to smoothly flow indoor air.

A second suction filter 1124 may be installed in the second suction port 1110. The second suction filter 1124 filters the foreign substances in the air passing through the second suction grille 1120 and is formed to have a size corresponding to the second suction port 1110.

A first suction port 1130 is formed in a lower portion of the rear case 1100 so that room air can be sucked into the first receiving space.

The first suction port 1130 may further include a first suction filter frame 1142 so that the first suction filter 1144 can be supported.

The first suction port 1130 may be shielded by the first suction grill 1140. The first suction grille 1140 guides indoor air into the first accommodation space and prevents foreign matter from entering the first accommodation space.

A first suction filter 1144 may be installed in the first suction port 1130. The first suction filter 1144 filters the foreign substances in the air passing through the first suction grille 1140 and is formed to have a size corresponding to the first suction port 1130.

The lower appearance of the mobile air conditioner (10) of the present invention can be formed by the base plate (100). The base plate 100 is coupled with the lower ends of the front case 1000 and the rear case 1100 and supports a plurality of components to be described below.

A plurality of moving wheels 150 are installed on the bottom surface of the base plate 100. The mobile wheel 150 is provided to facilitate movement of the mobile air conditioner 10, and one each of the mobile wheels 150 may be installed at each corner of the rectangular base plate 100.

This is to prevent the mobile wheel 150 from falling when the mobile air conditioner 10 moves by supporting the corner portions of the base plate 100.

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

The first heat exchanger 500 may be installed at the center portion of the base plate 100 as shown in FIG. This is to allow the air introduced through the first intake port 1130 disposed at the rear side to be discharged to the rear after passing through the first heat exchanger 500 laterally.

The manner in which the first heat exchanger 500 is installed in the base plate 100 may be determined by the flow of air. For example, if the first suction port 1130 is disposed at the front, the first heat exchanger 500 may be installed to the left and right at the center portion.

Hereinafter, a description will be made on the basis of a diagram considering an efficient arrangement of components installed on the base plate 100. FIG.

The first heat exchanger 500 serves to cool (or heat) the refrigerant by heat exchange between the refrigerant flowing in the first refrigerant pipe 510 and the air passing between the first heat radiation plate 520.

That is, the air introduced into the first accommodation space through the first suction grille 1140 formed in the lower part of the rear case 1100 flows through the first heat exchanger 500 while flowing through the first heat exchanger 500 And the heat-exchanged air passing through the first heat exchanger (500) is discharged to the outside through the piping (1300).

A compression unit 200 may be installed on one side of the base plate 100. The compression unit 200 may be provided with 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 supporting rigidity of the compressor 202 mounted on the base plate 100.

An accumulator 203 may be installed on the side of the compressor 202. The accumulator 203 serves to filter out the liquid refrigerant and to cause only the gaseous refrigerant to flow into the compressor 202.

Although not shown in the drawings, the base plate 100 may be provided with a condensate drainage module (400 in FIG. 9). The condensate drainage module (400 in FIG. 9) senses the amount of condensed water accumulated on the upper surface of the base plate 100 and discharges the condensed water to the outside. A detailed description thereof will be described below.

The base plate 100 may be provided with a support angle 950 in close contact with the compression unit 200. In other words, the support angle 950 is vertically installed on the base plate 100 to support a load acting on the compression unit 200 in a lateral direction.

 A first blowing orifice 323 is provided at one side of the first heat exchanger 500 in the vicinity of the first heat exchanger 500.

The first blowing orifice 323 supports a number of components such as the second blowing orifice 722 and the second blowing guide 720 which will be described below and the air that has passed through the first heat exchanger 500 .

 A first blowing guide 322 is provided on one side of the first blowing orifice 323. The first blowing guide 322 can guide the flow of air together with the first blowing orifice 323.

 Between the first blowing orifice 323 and the first blowing guide 322, a first impeller 340 for forcing the flow of air is positioned. The first impeller 340 is rotated by the first blowing motor 330 to discharge air to the first blowing port 324.

The first blowing port 324 is connected to the exhaust port 1180 formed in the rear case 1100. The air blown into the first blowing unit 300 by the rotation of the first blowing motor 330 flows through the first blowing port 324, And then discharged to the outside through an exhaust port 1180 connected to the exhaust port 1180.

The first blowing grill 310 may be inserted into the first blowing hole 324. The first blowing grill 310 serves to prevent foreign matter from being introduced into the first blowing unit 300 through the first blowing port 324.

A partition plate 600 is installed at the center of the accommodation space. The partition plate 600 may have a rectangular shape, as shown in the figure.

The partition plate 600 serves to collect the condensed water generated in the second heat exchanger 800 to be described below and to support a plurality of components and to divide the interior space of the movable type air conditioner 10 into upper and lower sections Can play a role.

 In general, the integral type mobile air conditioner 10 is divided into an outdoor side and an indoor side, and the partition plate 600 is disposed inside the movable type air conditioner 10 of the present invention on the outdoor side And the indoor side.

That is, an outdoor side (heat radiation side) corresponding to an outdoor unit (in a separate type air conditioner) is formed in a first accommodation space disposed at the lower portion with respect to the partition plate 600, (On the heat absorbing side) corresponding to the indoor heat exchanger (in the separate type air conditioner).

Alternatively, it is possible to form the indoor side (heat absorbing side) in the first housing space and the outdoor side (heat radiation side) in the second housing space with the reverse structure.

The following description will be made with reference to a structure in which an outdoor side (radiation side) is formed in a first accommodation space and a room side (heat absorption side) is formed in a second accommodation space.

A second heat exchanger 800 may be installed on the upper surface of the partition plate 600. The second heat exchanger 800 may include a second refrigerant pipe 810 and a second heat radiation plate 820 through which the refrigerant can flow.

The second heat exchanger 800 may be installed across the left and right sides of the upper portion of the partition plate 600, as shown in FIG. This is because the air introduced through the second intake port 1110 disposed at the rear passes through the second heat exchanger 800 rearward and is then changed in direction by the second air blowing unit 700 so as to be discharged forward It is for this reason.

The second heat exchanger 800 may serve as an evaporator. The refrigerant flowing in the second refrigerant pipe 810 and the air passing between the second heat radiation plate 820 perform heat exchange. The refrigerant absorbs heat from the air to be phase-changed into gas, and the air can absorb the heat from the refrigerant, and the temperature can be lowered.

The air introduced into the second accommodation space through the second intake port 1110 formed in the upper portion of the rear case 1100 passes through the second heat exchanger 800 and flows into the second heat exchanger 800 through the refrigerant flowing in the second heat exchanger 800 Exchanged with each other, and the heat-exchanged air passing through the second heat exchanger 800 is discharged to the outside (indoor) through the discharge port 1044.

A second blowing orifice 722 is provided on one side of the second heat exchanger 800 in the vicinity of the second heat exchanger 800. The second blowing orifice 722 can guide the air that has passed through the second heat exchanger 800 forward.

 A second air blowing guide 720 is provided on one side of the second air blowing orifice 722. The second blower guide 720 can guide the flow of air together with the second blowing orifice 722. [

A second impeller 740 is disposed between the second blowing orifice 722 and the second blowing guide 720 to forcibly flow the air. The second impeller 740 is rotated by the second blowing motor 730 to discharge the air to the second blowing port 725.

The second blowing port 725 is communicated with the discharge port 1044 so that the air introduced into the second blowing unit 700 by the rotation of the second blowing motor 730 is discharged through the discharge port 1044 communicated with the second blowing port 725 To the outside of the room.

On the other hand, a control box 900 may be installed on one side of the partition plate 600. The control box 900 is a place where a plurality of electric components for controlling the operation of the mobile air conditioner 10 are embedded.

The control box 900 may be installed through the partition plate 600 with the upper portion of the control box 900 protruding upward from the partition plate 600 and the lower portion of the control box 900 extending below the partition plate 600 Can be protruded.

In the mobile type air conditioner 10 according to the embodiment of the present invention, the rear surface of the rear case 1100 may be stepped. Specifically, the front and rear lengths of the rear case 1100 are different from each other in the upper and the rear half. That is, the rear longitudinal length of the rear case 1100 may be larger than the front longitudinal length of the upper portion.

In consideration of the arrangement of the components installed in the first accommodation space and the flow of the air, the second heat exchanger 800 is laterally installed in the second accommodation space, The first heat exchanger 500 is installed in the first accommodation space in front and rear. In addition, since the size of the lower portion is larger than that of the upper portion and the center of gravity is concentrated on the lower portion, the structure is more stable.

As a result of the difference in the front and rear lengths of the lower portion and the upper portion of the rear case 1100, a stepped surface may be formed in the center portion of the rear case 1100. However, The rear case 1100 may be curved between the lower part and the upper part.

An exhaust port 1180 may be formed in the lower portion of the rear case 1100 so as to pass through the upper and lower portions. The air outlet 1180 is connected to the first air outlet 324 and is a portion where the air is discharged from the first heat exchanger 500 and the piping pipe 1310 is fastened. Therefore, the exhaust port 1180 preferably has a size and shape corresponding to one end of the pipe pipe 1310.

The first suction grille 1140 described above is formed at a lower portion of the rear case 1100. The first suction grille 1140 is formed only at a lower one side portion of the rear case 1100, .

That is, the first suction grille 1140 may be formed over the entire lower portion of the rear case 1100 in accordance with the flow of air introduced into the first accommodation space and discharged. However, when the first heat exchanger 500 is installed at the central portion of the base plate 100 in a back-and-forth direction, air is introduced into one side of the lower portion of the rear case 1100, It is preferable that a suction grill 1140 is formed and an exhaust port 1180 is formed on the other side.

The reason why the first suction grille 1140 is formed only on one side of the rear case 1100 is that the air sucked through the first suction grille 1140 must pass through the first heat exchanger 500. That is, the air sucked from the rear through the first suction grille 1140 passes through the first heat exchanger 500 and can be discharged to the rear.

A plurality of fastening protrusions for fastening the front case 1000 are formed at the front end of the rear case 1100 so that the fastening members such as screws penetrate the front case 1000 and the front case 1000.

Alternatively, the front case 1000 may have a locking groove corresponding to the locking protrusion, so that the locking protrusion and the locking groove engage with each other so that the front and rear cases 1000 and 1100 can be fastened.

The front case 1000 forms an outer appearance of the front surface, and can partially form an outer appearance of the side surface and the upper surface. Although not shown, a reinforcing panel may be further provided on the rear surface of the front case 1000.

Such a reinforcing panel can serve as a soundproof and sound-absorbing function for absorbing or shielding noise generated in the mobile air conditioner 10. The reinforcing panel is preferably made of a material capable of absorbing moisture (condensed water, etc.) generated in the mobile air conditioner 10.

The front panel may be fixed to the front case 1000 in a double manner. That is, the front panel can be fixedly mounted on the front case 1000 by the attaching and fixing means and the fixing means, respectively.

7 is a perspective view of the partition plate 600. As shown in Fig.

7, the partition plate 600 has a substantially rectangular outer shape corresponding to the formation of the transverse section of the accommodation space, and is provided at a central portion between the front case 1000 and the rear case 1100, The space defined between the rear case 1000 and the rear case 1100 is divided into upper and lower portions.

On the upper surface of the partition plate 600, a plurality of second bottom compartment ribs 602 are formed. The second bottom partition ribs 602 form a plurality of chambers on the top surface of the partition plate 600 to form a space through which condensed water can flow.

More specifically, a plurality of second bottom dividing ribs 602 are formed at equal intervals on the upper surface of the partition plate 600. The second bottom dividing ribs 602 are formed integrally with the partition plate 600 , And upward from the upper surface of the partition plate (600).

The second bottom partition rib 602 prevents a large number of components such as the second heat exchanger 800 installed on the upper portion of the partition plate 600 from being in close contact with the upper surface of the partition plate 600, A predetermined space is formed so that the condensed water dropped in the condensing unit 800 can easily flow from the upper surface of the partition plate 600.

 In the partition plate 600, a plurality of bottom condensate holes 604 are formed through the upper and lower portions. The bottom condensed water hole 604 causes the condensed water falling from the second heat exchanger 800 to move to the lower side of the partition plate 600.

A condensate drop guide (not shown) may further be formed on the bottom surface of the partition plate 600. The condensate drop guide is for allowing the condensate flowing to the bottom surface of the partition plate 600 through the bottom condensate hole 604 to fall directly and smoothly.

That is, the condensed water drop guide serves to attract the condensed water, which has been moved to the bottom surface of the partition plate 600, to fall immediately without flowing into the other parts.

Accordingly, the condensate drop guide protrudes downward from the bottom surface of the partition plate 600. [ More specifically, a condensate drop guide extends downwardly from each bottom condensate hole 604.

That is, the condensate drop guide extends to the lower side of the bottom condensed water hole 604 and may have a cylindrical shape corresponding to the bottom condensed water hole 604.

Meanwhile, in the partition plate 600, a plurality of grooves may be formed to avoid interference with surrounding components.

In an embodiment, the control box installation hole 620 may be formed in the front right portion of the partition plate 600 so as to open forward. The control box mounting hole 620 is preferably formed in a size and shape corresponding to the cross-section of the control box 900. Therefore, the control box 900 can be installed across the control box installation hole 620.

At the right end of the partition plate 600, a pipe passage groove 624 through which the refrigerant pipe 350 passes may be formed.

That is, the refrigerant flowing between the first heat exchanger 500 and the compressor 202 and the second heat exchanger 800 flows by the refrigerant pipe 350 formed of a pipe, Through the pipe passage grooves 624. The pipe- The pipe passage groove 624 may have a shape (as viewed from above) as shown.

On the other hand, a fastening groove or a fastening protrusion for fastening the case to the case may be formed near the left and right side end edges of the partition plate 600.

8 is a perspective view of the base plate 100. As shown in Fig.

As shown in FIG. 8, the base plate 100 may have a substantially rectangular outer shape corresponding to the formation of the bottom cross-section of the receiving space.

On the upper surface of the partition plate 600, a plurality of first bottom compartment ribs 102 are formed. The first bottom dividing rib 102 forms a plurality of chambers on the upper surface of the base plate 100 to form a space through which condensed water can flow.

A plurality of first bottom dividing ribs 102 are formed on the upper surface of the base plate 100 so that condensed water flowing into the upper surface of the base plate 100 flows into the condensed water outlet (130).

The first bottom partition ribs 102 may be integrally formed with the partition plate 600 and protrude upward from the upper surface of the partition plate 600.

The first bottom dividing rib 102 prevents a large number of components such as the second heat exchanger 800 installed on the upper portion of the partition plate 600 from being brought into close contact with the upper surface of the base plate 100, A predetermined space is formed so that the condensed water generated in the unit 500 and dropped can easily flow from the upper surface of the base plate 100.

The base plate 100 may be provided with a splash fan 110 composed of a splash wing 112 and a splash motor 114 on one side of the flow path of the condensed water formed along the first bottom partition rib 102 formed on the upper surface .

The splash wing 112 can be rotationally driven by a splash motor 114 connected to the rotation shaft at the center of the splash fan 110. [

The splash wing 112 can cause the condensed water flowing in the passage of the condensed water formed along the first bottom partition rib 102 to be sprayed toward the first heat exchanger 500 side.

This is to facilitate the heat exchange of the refrigerant flowing in the first heat exchanger 500 by spraying the condensed water to the first heat exchange side.

FIG. 9 is a view showing a condensate drainage module 400 of the mobile type air conditioner 10 according to the present invention, and FIGS. 10 and 11 are a partial perspective view and a partial cross-sectional view showing an S region of FIG.

9-11, the condensate drain module 400 includes a water level sensor 410 and a drain pump 420. Here, the water level sensor 410 and the drain pump 420 may be fixed to the drain module frame 430. However, in an embodiment of the present invention, the drain pump 420 may be omitted.

The water level sensor 410 may include a first water level sensor 412 and a second water level sensor 414. [ The first water level sensor 412 and the second water level sensor 414 may be fixed to the drain module frame 430. The first water level sensor 412 and the second water level sensor 414 may be arranged to be spaced apart from each other, and may be arranged to have different stepped portions.

Specifically, a difference in height between the one end of the first water level sensor 412 and one end of the second water level sensor 414 may be generated by the first interval D1. The first water level sensor 412 may be disposed at a lower position than the second water level sensor 414. [ At this time, the plane in which the first water level sensor 412 is fixed and the plane in which the second water level sensor 414 is fixed may be different from each other. The first water level sensor 412 and the second water level sensor 414 may be fixed to the drain module frame 430 such that the first water level sensor 412 and the second water level sensor 414 are spaced apart from each other by the second gap D2.

For example, the first level sensor 412 has a first floating portion 412f having a specific gravity lower than that of water. When the water level of the condensed water that has been accumulated on the base plate 100 rises, the floating portion 412f is raised together by buoyancy. At this time, the position of the floating part 410f can be sensed through the sensor part (412s in FIG. 19) disposed at a predetermined height of the first water level sensor 412, and the floating part 410f can be detected by the sensor part 412s The first water level sensor 412 can determine that the current water level is higher than the position of the sensor unit. At this time, the first water level sensor 412 and the second water level sensor 414 include components substantially the same and can operate substantially the same.

At this time, the first water level sensor 412 can sense the first water level, and the second water level sensor 414 can sense the second water level higher than the first water level. Since the first water level sensor 412 and the second water level sensor 414 are disposed at different heights, the height of the water level that can be sensed also changes.

The first and second water level sensors 412 and 414 transmit a sensing signal to the control box 900 indicating that the condensed water has reached a certain water level when the water level of the condensed water exceeds a predetermined specific water level. The control box 900 can control the operation of each component included in the mobile air conditioner 10 based on the received data. A detailed description thereof will be described below.

The drain pump 420 may drain the condensed water accumulated in the base plate 100 to the outside through the drain pipe 450. The drain pump 420 may have a compression pump that generates a high pressure and may use the generated pressure to move the condensate to a relatively low pressure outside. At this time, the condensed water may be discharged to the outside through the drain pipe 450 connected to one side of the drain pump 420.

The drain module frame 430 fixes the water level sensor 410 and the drain pump 420. The drainage module frame 430 may include a fixing plate 435 on which the first level sensor 412 and the second level sensor 414 are installed, As shown in FIG.

The drain module frame 430 may be formed integrally with the first blowing guide 322 of the first blowing unit 300. The drain module frame 430 may be formed in the same process (for example, a press forming process) as the first blowing guide 322 and is made of the same material. The drainage module frame 430 and the first blowing guide 322 are integrally formed so that the movable air conditioner 10 is provided with a separate fixed frame capable of fixing the water level sensor 410 and the drain pump 420 Can be omitted. Accordingly, the mobile air conditioner 10 can reduce the total number of components of the condensate drainage module 400, and can eliminate the additional assembly airflow generated by the separate fixed frame. In addition, the manufacturing cost can be reduced by simplifying the assembling structure of the water level sensor 410 and the drain pump 420.

However, the present invention is not limited thereto, and the drainage module frame 430 may be formed separately from the first blowing guide 322. [0054]

The drain pipe 450 may be connected to a discharge port whose one end is connected to the drain pump 420 and the other end is directed to the outside. The water discharge pipe 450 may be arranged to be curved along the outer surface of the first air blowing guide 322. That is, the water pipe 450 is arranged to be in contact with the upper surface of the first airflow guide 322, and is arranged to bend along the curvature of the upper surface.

Fig. 12 shows a section taken along the line A-A in Fig. 11, and Fig. 13 shows a section taken along the line B-B in Fig.

12, the drain pump 420 may be fixed to the inner surface of the top plate of the drain module frame 430. [ The drain pump 420 may be fixed to the inner surface of the drain module frame 430 by a coupling member 431 (e.g., a bolt). At this time, the drain module frame 430 may be arranged to cover the upper part of the drain pump 420 so that condensate does not permeate into the internal circuit of the drain pump 420.

13, the fixing plate 435 may have fixing grooves 432 and 434 for inserting the first level sensor 412 and the second level sensor 414, respectively.

The first water level sensor 412 may be inserted into and fixed to the first fixing groove 432 and the second water level sensor 414 may be inserted into the second fixing groove 434 and fixed. At this time, the fixing grooves 432 and 434 may be spaced apart by a second distance D2.

A plurality of wires respectively connected to the water level sensor 410 and the drain pump 420 may be arranged to pass through the openings 437 formed in the sides of the drain module frame 430. [ A plurality of wires may be connected to the control box 900 to deliver signals between the level sensor 410 and the drain pump 420 and the control box 900.

14 and 15 are views for explaining the operation of the drain pump of the mobile type air conditioner according to the embodiment of the present invention.

14 and 15, the drain pipe 450 may have one end connected to the drain pump 420 and the other end connected to an outlet connected to the outside. The drain pump 420 discharges the condensed water collected in the base plate 100 to the outside through the drain pipe 450. The condensed water moves upward along the drain pipe 450 and is discharged to the discharge port connected to the other end of the drain pipe 450.

The water discharge pipe 450 may be arranged to be curved along the outer surface of the first air blowing guide 322. The water discharge pipe 450 is arranged to be in contact with the upper surface of the first airflow guide 322, and is arranged to bend along the curvature of the upper surface.

At this time, the water pipe 450 is disposed to pass between the partition plate 600 and the first air guide 322, and may be connected to a discharge port communicating with the outside of the mobile air conditioner 10. Although not clearly shown in the drawing, a reservoir capable of storing the discharged condensed water is provided at one side of the discharge port to collect the discharged condensed water.

16 to 18 are views for explaining the operation of the mobile type air conditioner and the flow of air according to the embodiment of the present invention.

Hereinafter, the operation of the mobile air conditioner 10 according to the present invention will be described with reference to FIGS. 16 to 18. FIG.

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

The mobile type air conditioner 10 according to the present invention can be used for cooling or heating. Here, the case where the mobile type air conditioner 10 according to the present invention is used for cooling as described above will be described as an example.

At this time, the first heat exchanger 500 serves as a condenser, and the second heat exchanger 800 serves as an evaporator. A refrigerant pipe (350) is connected between the compressor (202) and the first heat exchanger (500) and the second heat exchanger (800) to guide the flow of the refrigerant.

Accordingly, when the gas refrigerant is compressed from the compressor 202 to be in a high-temperature and high-pressure state and flows into the first heat exchanger 500, the refrigerant is condensed by heat exchange with the outside air in the first heat exchanger 500.

The condensed refrigerant is then expanded while passing through the expansion valve and flows into the second heat exchanger (800).

The refrigerant flowing into the second heat exchanger (800) exchanges heat with the outside air and evaporates. Therefore, the refrigerant becomes a gaseous state, and at this time also the refrigerant in a liquid state remains, and actually two-phase refrigerant is mixed.

The refrigerant passes through the accumulator 203 and then flows back to the compressor 202 to complete the circulation cycle of the refrigerant.

Meanwhile, the air passes through the first heat exchanger 500 and the second heat exchanger 800 to perform heat exchange.

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

That is, when the first blowing motor 330 is driven by a power source externally applied, the first impeller 340 connected to the axis of the first blowing motor 330 rotates to generate air flow will be.

Accordingly, the rear air can be introduced through the first suction port 1130 formed in the lower portion of the rear case 1100. [ The air introduced through the first inlet port 1130 is diverted to flow laterally and passes through the first heat exchanger 500.

The temperature of the air passing through the first heat exchanger 500 rises. That is, since the first heat exchanger 500 serves as a condenser, heat is received from the refrigerant flowing in the first heat exchanger 500, and the air is in a high temperature state.

The high-temperature air having passed through the first heat exchanger (500) passes through the first blowing orifice (323) and flows into the center of the first impeller (340). The air introduced into the central portion of the first impeller 340 flows radially by the rotation of the first impeller 340 and is guided in the first air guide 322 and the first air blowing orifice 323 to be discharged upward.

The hot air, which is guided through the first blowing guide 322 and the first blowing orifice 323 and is discharged upward, is completely discharged to the outside of the building through the piping 1300.

Next, the flow of air (represented by a white arrow in the drawing) occurring in the heat absorption side (second accommodation space) is examined. The air flow at this time is basically generated by the second impeller 740.

That is, when the second blowing motor 730 is driven by an external power source, the second impeller 740 connected to the axis of the second blowing motor 730 rotates to generate air flow will be.

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

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

The low temperature air having passed through the second heat exchanger 800 flows through the second blowing orifice 722 and flows 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. This air is guided in the second air blowing guide 721 and the second air blowing orifice 722, .

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

Next, look at the condensate flow.

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

The condensed water generated in this process falls to the bottom of the second heat exchanger 800 and falls on the upper surface of the partition plate 600. The condensed water dropped on the upper surface of the partition plate 600 is guided and flowed by the second bottom partition rib 602 and moves downward through the partition plate 600 through the bottom condensed water hole 604 do.

The condensed water that has passed through the bottom condensate hole 604 and moves to the lower side of the partition plate 600 flows down along the inner surface of the condensed water drop guide, falls at the lower end of the condensed water drop guide, and then falls downward.

The condensed water dropped downward can flow into the upper surface of the base plate 100. The condensed water flowing into the upper surface of the base plate 100 can flow along the flow path formed by the first bottom dividing rib (102 in FIG. 8) formed on the upper surface of the base plate 100.

The splash fan 110 can cause the condensate flowing through the passage of the condensed water formed along the first bottom partition rib 102 to be sprayed toward the first heat exchanger 500 side. This facilitates the heat exchange of the refrigerant flowing in the first heat exchanger 500 by spraying the condensed water to the first heat exchange side, and evaporates the condensed water to discharge it to the outside.

The control box 900 can control the operation of each component of the mobile air conditioner 10 according to the level of the condensed water collected in the base plate 100.

Specifically, the control box 900 receives a sensing signal for the level of the condensed water from the level sensor 410. As described in detail above, the water level sensor 410 can sense the first water level and the second water level. At this time, the second water level is set higher than the first water level.

When the water level of the condensed water is lower than the first water level, the mobile air conditioner 10 operates normally. At this time, the splash fan 110 can operate at a low speed (for example, 2200 RPM). However, this is only an example, and the present invention is not limited thereto.

The control box 900 increases the driving speed of the splash fan 110 when the water level of the condensed water is higher than the first water level and lower than the second water level. Accordingly, a larger amount of condensed water flowing through the passage of the condensed water can be sprayed toward the first heat exchanger 500, and a part of the sprayed condensed water receives heat from the refrigerant flowing in the first heat exchanger 500 Evaporated. At this time, the splash fan 110 can operate at a high speed (for example, 4400 RPM). However, this is only an example, and the present invention is not limited thereto.

The high-temperature air including the evaporated condensed water that has passed through the first heat exchanger 500 passes through the first blowing orifice 323 and flows into the center of the first impeller 340. The air introduced into the central portion of the first impeller 340 flows radially by the rotation of the first impeller 340 and is guided in the first air guide 322 and the first air blowing orifice 323 to be discharged upward.

The hot air, which is guided through the first blowing guide 322 and the first blowing orifice 323 and is discharged upward, is completely discharged to the outside of the building through the piping 1300.

At this time, the control box 900 can control the operation of the compressor 202 so that the temperature of the refrigerant supplied to the first heat exchanger 500 operating as a condenser is raised. As the temperature of the refrigerant rises, larger amounts of condensed water evaporate and can be discharged to the outside.

In addition, the control box 900 can reduce the amount of condensed water generated in the first heat exchanger 500 by lowering the operation speed of the condenser.

In addition, the control box 900 may increase the rotational speed of the first impeller 340 to allow the evaporated condensed water to be quickly discharged to the outside.

On the other hand, when the water level of the condensed water is higher than the second water level, the control box 900 drives the drain pump 420 to discharge the condensed water to the outside through the drain pipe 450. This is for quickly discharging the condensed water to the outside when the drainage can not be performed smoothly only by controlling the operation speed of the splash fan 110 or the compressor 202 and reaches the full water level. In this case, the control box 900 can stop the operation of the compressor 202 or stop the operation of the entire components except the drain pump 420, but the present invention is not limited thereto.

The control box 900 operates the drain pump 420 only when the water level of the condensed water is higher than the second water level, thereby minimizing the operation of the drain pump 420 in the course of discharging the condensed water. By minimizing the operation of the drain pump 420 having a relatively large operation noise and a large amount of electric power to be consumed, the operation noise of the mobile air conditioner and the amount of electric power used can be reduced and the energy efficiency can be improved.

In addition, in another embodiment of the present invention, the control box 900 stops all operations of the mobile air conditioner 10 when the water level of the condensed water is higher than the second water level, and informs the user of the full water level (for example, , A notification tone or an alert display).

19 and 20 are views for explaining another embodiment of the water level sensor included in the mobile type air conditioner according to the embodiment of the present invention.

19, the water level sensor 410 may be constituted by first and second water level sensors 412 and 414 (type A) capable of sensing only one water level, And a third water level sensor 415 (B type).

First, in the case of the A-type level sensor 410, the first level sensor 412 and the second level sensor 414 are included. Hereinafter, the first water level sensor 412 and the second water level sensor 414 have the same configuration, so that the first water level sensor 412 will be described as an example.

The first water level sensor 412 includes a floating portion 412f having a lower specific gravity than the condensed water and a pillar portion 4121 for guiding the floating portion 412f up and down. The floating portion 412f has a donut shape and can move up and down along the pillar portion 4121 with the pillar portion 412l inserted into the center of the center hole.

The upper guard portion 412a and the lower guard portion 412b may be formed on the upper and lower portions of the pillar portion 412l such that the floating portion 412f is not separated from the pillar portion 412l. The floating portion 412f can move up and down along the pillar portion 4121 in the region between the upper guard portion 412a and the lower guard portion 412b.

A sensing portion 412s is provided in a region between the upper guard portion 412a and the lower guard portion 412b of the pillar portion 4121. When the floating unit 412f overlaps the sensing unit 412s, the sensing unit 412s senses the floating unit 412f to generate a sensing signal. The generated sensing signal is transmitted to the control box 900. For example, the floating unit 412f may include a magnet, and the sensing unit 412s senses a change in the magnetic flux, and when the floating unit 412f overlaps the sensing unit 412s, Can be output. However, this is only an example, and the present invention is not limited thereto.

Since the first level sensor 412 and the second level sensor 414 are installed to have a step difference, each of the first and second level sensors 412 and 414 senses different levels of water level, As shown in FIG.

The construction of the floating portion 415f, the pillar portion 4151, the upper guard portion 415a and the lower guard portion 415b of the B type third water level sensor 415 is the same as that of the first water level sensor 412).

However, in the case of the third water level sensor 415, at least two sensing units 415sa and 415sb spaced from each other are provided in an area between the upper guard part 415a and the lower guard part 415b of the pillar part 415l . At this time, the first sensing unit 415sa is disposed below the second sensing unit 415sb, and each of the sensing units 415sa and 415sb can sense different levels.

As shown in FIG. 20, the third water level sensor 415 can sense different levels depending on the degree of overlap between the sensing units 415sa and 415sb and the floating unit 415f. Accordingly, one third water level sensor 415 can replace the A type water level sensor 410 having a plurality of water level sensors 412, 414. In this case, as the number of level sensors to be installed is reduced, the size of the condensate drainage module 400 can be reduced and the manufacturing cost of the condensate drainage module 400 can be reduced.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims.

10: Portable air conditioner 100: Base plate
102: first bottom dividing rib 110: splash fan
112: splash wing 114: splash motor
130: condensate outlet 150: moving wheel
200: compression unit 202: compressor
203: Accumulator 204: Compressor frame
300: first blower unit 310: first blower grill
322: first blowing guide 323: first blowing orifice
324: first blowing port 330: first blowing motor
340: First impeller 350: Refrigerant piping
400: Condensate drain module 410: Water level sensor
412: first water level sensor 414: second water level sensor
420: Drain pump 430: Drain module frame
431: coupling member 435: fixed plate
437: opening part 450: drain pipe
500: first heat exchanger 510: first refrigerant pipe
520: first heat dissipating plate 600: partition plate
602: second bottom compartment rib 604: bottom condensate hole
620: Installation of control box 624: Passing through pipe
700: second blowing unit 710: second blowing grill
720: second blowing guide 722: second blowing orifice
724: second blowing part 725: second blowing hole
726: Ventilation channel forming projection 730: Second blowing motor
740: Second impeller 750: Discharge louver
751: Discharge lid 752: Discharge rib
753: Vertical discharge rib 754: Horizontal discharge rib
756: rib flow path 758: louver rotating shaft
760: louver installation groove 770: louver motor
800: second heat exchanger 810: second refrigerant pipe
820: second heat radiating plate 900: control box
950: support angle 1000: front case
1020: Operation unit 1040: Discharge frame
1041: Discharging part 1044: Discharging part
1046: Discharge channel forming projection 1050: Discharge channel
1100: rear case 1110: second inlet
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 part
1180: exhaust port 1200: installation kit
1300: piping part 1310: piping pipe
1320: Piping nozzle 1330: Piping connector
1340: Plumbing grill

Claims (13)

A case having an inlet, an outlet, and a discharge unit;
A base plate coupled to the lower portion of the case;
A receiving space defined by the case and the base plate;
A first heat exchanger installed inside the accommodation space;
A first blowing unit installed adjacent to the first heat exchanger inside the accommodation space;
A condensate drain module including a level sensor for sensing the level of condensed water collected in the base plate;
A splash fan provided on a flow path formed on an upper surface of the base plate; And
And a control box for controlling operations of the first heat exchanger, the first blowing unit, the condensate drain module, and the splash fan,
The control box includes:
When the level of the condensed water sensed by the water level sensor is higher than the first water level and lower than the second water level,
Portable air conditioner.
The method according to claim 1,
Further comprising a compressor for compressing the refrigerant supplied to the first heat exchanger,
The control box includes:
And a controller for controlling the operation of the compressor so that the temperature of the refrigerant provided to the first heat exchanger is raised when the water level of the condensed water detected by the water level sensor is higher than the first water level and lower than the second water level, .
3. The method of claim 2,
Wherein the water level sensor includes a first water level sensor for sensing the first water level and a second water level sensor for sensing the second water level,
Wherein the first and second water level sensors are installed to have steps in the drain module frame.
3. The method of claim 2,
The water level sensor comprises:
A floating portion having a lower specific gravity than the condensed water;
A pillar portion for guiding the floating portion up and down,
And first and second sensing units provided at different heights in the pillar to sense the position of the floating unit.
The method according to claim 1,
Wherein the condensate drainage module further comprises a drain pump for discharging the condensed water to the outside through a drain pipe,
The control box may further include a control box for controlling the drain pump to be operated when the water level of the condensed water is higher than the second water level
Portable air conditioner.
6. The method of claim 5,
Wherein the condensate drainage module further comprises a drain module frame for fixing the level sensor and the drain pump.
The method according to claim 6,
Wherein the drain pump is fixed to the inner surface of the drain module frame such that the drain pump module is covered by the drain module frame.
6. The method of claim 5,
And a lower end of the drain pump is disposed to be spaced apart from an upper surface of the base plate.
6. The method of claim 5,
Wherein the drain pipe is arranged to be curved along the outer surface of the air guide of the first blowing unit and has one end connected to the drain pump and the other end connected to the external discharge port.
A receiving space defined by front and rear cases forming front and rear outer tubes and a base plate coupled with the front and rear cases below;
A partition plate for vertically dividing the accommodation space into a first accommodation space and a second accommodation space;
A first heat exchanger installed inside the first accommodation space,
A first blowing unit installed adjacent to the first heat exchanger in the first accommodation space;
A second heat exchanger installed inside the second accommodation space;
A second blowing unit installed adjacent to the second heat exchanger in the second accommodation space; And
And a condensate drain module installed adjacent to the first blower unit,
The condensate drainage module includes a level sensor for sensing first and second different levels of condensed water collected in the base plate,
And a drain pump for discharging the condensed water to the outside through a drain pipe
Portable air conditioner.
11. The method of claim 10,
Wherein the water level sensor includes a first water level sensor for sensing the first water level and a second water level sensor for sensing the second water level,
Wherein the first and second water level sensors are installed so as to have a step difference.
11. The method of claim 10,
A splash fan provided on a flow path formed on an upper surface of the base plate,
Further comprising a control box for controlling the operation of each component included in the mobile air conditioner,
The control box includes:
And when the water level of the condensed water detected by the water level sensor is higher than the first water level and lower than the second water level, the operation of the splash fan, the operation speed of the first and second air blowing units,
And the drain pump is driven when the water level of the condensed water is greater than the second water level.
13. The method of claim 12,
Further comprising a compressor for compressing the refrigerant supplied to the first heat exchanger,
The control box includes:
And a controller for controlling the operation of the compressor so that the temperature of the refrigerant provided to the first heat exchanger is raised when the water level of the condensed water detected by the water level sensor is higher than the first water level and lower than the second water level, .

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