JP7341325B2 - Outdoor unit - Google Patents

Description

The present disclosure relates to an outdoor unit having a bottom plate in which a drainage hole is formed.

Some outdoor units have a bottom plate provided with drain holes to drain condensed water generated on the surface of the heat exchanger to the outside of the unit. Depending on the installation environment of the outdoor unit, it may be necessary to drain condensed water using a hose, so some models include a socket part in the drain hole, which allows the drain hole to be connected to the drain hose.

Patent Document 1 discloses a configuration in which an air suction port is provided on the back surface of an outdoor unit, and a socket component is attached below the air suction port. It has been proposed that this configuration ensures the number of heat exchanger stages and improves the ability to draw out and store the drain hose.

Utility Model Publication No. 58-150707

In the outdoor unit of Patent Document 1, the drainage hole is provided on the side surface of the bottom plate, so the full water position rises and drainage performance deteriorates. Condensed water that is not drained and accumulates inside the machine causes corrosion of the sheet metal parts that make up the bottom plate of the outdoor unit. Furthermore, condensed water that is not drained and accumulates inside the machine freezes during heating operation at low outside temperatures. If the condensed water freezes and blocks the drain hole, the ice can grow and come into contact with piping or the fan, causing damage.

The present disclosure has been made to solve the above problems, and an object of the present disclosure is to provide an outdoor unit with improved drainage of condensed water from the bottom plate.

An outdoor unit according to the present disclosure includes a bottom plate having a bottom surface on which a heat exchanger is placed, a wall surface erected from the edge of the bottom surface, and a drainage hole, and a bottom plate attached to the bottom plate and having a guide surface. , a drain base having a rising surface that is continuous from the guide surface and extends upward, and a connection hole formed in the rising surface and to which a drain hose is connected, and the drainage hole is connected to the bottom surface from the bottom surface. The drain base is provided astride a wall surface, and the guide surface closes the drainage hole on the bottom surface from below, the rising surface runs along the wall surface, and the connection hole closes the drainage hole on the wall surface from below. It is fixed to the bottom plate from the outside of the bottom plate so as to face the hole, and the guide surface of the drain base is curved downward in a shape along the circumference of the connection hole .

According to the outdoor unit according to the present disclosure, condensed water flows out from the drainage hole formed across the bottom surface of the bottom plate and the wall surface, and is guided to the connection hole by the guide surface of the drain base and drained, so that condensation water condenses. An outdoor unit with improved water drainage performance can be obtained.

It is a perspective view showing the appearance of the outdoor unit concerning this embodiment. It is a perspective view showing the inside of the outdoor unit concerning this embodiment. FIG. 2 is a perspective view of the bottom plate according to the present embodiment seen from the front. FIG. 3 is an enlarged perspective view of the bottom plate according to the present embodiment. It is a perspective view showing the back of the outdoor unit concerning this embodiment. FIG. 2 is an enlarged perspective view of the periphery of the drain base according to the present embodiment, seen from the back. FIG. 2 is an enlarged perspective view of the drain base according to the present embodiment, viewed from the back. It is a schematic diagram explaining the flow of condensed water flowing toward the drain base from the bottom plate according to the present embodiment. FIG. 2 is an exploded perspective view illustrating connections between a bottom plate, a drain base, a socket, and a drain hose according to the present embodiment.

The outdoor unit 100 according to this embodiment will be described below. Note that in the following drawings, the size relationship of each component may differ from the actual one. In addition, in the following drawings, parts with the same reference numerals are the same or equivalent, and this is common throughout the entire specification. Further, the forms of the constituent elements shown throughout the specification are merely examples, and the present invention is not limited to these descriptions.

Moreover, in the following figures, the X direction indicates the left-right direction of the outdoor unit 100, and the arrow indicates the direction from the right to the left. The Y direction indicates the front-rear direction of the outdoor unit 100, and the arrow indicates the direction from the front to the rear. The Z direction indicates the vertical direction of the outdoor unit 100, and the direction from the bottom to the top is indicated by an arrow.

<Configuration of outdoor unit 100>
FIG. 1 is a perspective view showing the appearance of an outdoor unit 100 according to the present embodiment. FIG. 2 is a perspective view showing the inside of the outdoor unit 100 according to the present embodiment. As shown in FIGS. 1 and 2, the outdoor unit 100 has a casing composed of a front panel 1, a back panel 2, a right side panel 3, a left side panel 4, a top panel 5, and a bottom plate 6. . The front panel 1, the back panel 2, the right side panel 3, the left side panel 4, and the top panel 5 constitute an outer panel serving as a design component. The housing accommodates a compressor 12, a heat exchanger 13, and a propeller fan 14 mounted on the bottom plate 6. The inside of the housing is partitioned into a machine room 110 and a blower room 120 by a partition plate 10.

The partition plate 10 is disposed on the bottom plate 6 and is provided so as to extend upward from the bottom plate 6, as well as in the front-rear direction of the bottom plate 6. The partition plate 10 is provided so as to extend between the front panel 1 and the back panel 2. An electrical component box 10a is arranged at the upper edge of the partition plate 10.

The compressor 12 is housed in the machine room 110. The compressor 12 compresses the sucked refrigerant into a high-temperature, high-pressure gas refrigerant state and discharges it. The compressor 12 may be, for example, a rotary or scroll type compressor. Although not shown in the drawings, the machine room 110 is provided with refrigerant piping that connects the components constituting the refrigeration cycle circuit.

The blower room 120 houses a heat exchanger 13 and a propeller fan 14. The blower room 120 takes in air from outside the outdoor unit 100 via the heat exchanger 13, and discharges air inside the outdoor unit 100 to the outside via the air outlet 1a. The propeller fan 14 is arranged on the back side of the grill 1b that covers the air outlet 1a, and the heat exchanger 13 is arranged on the back side of the propeller fan 14. A motor fan for driving the propeller fan 14 is also attached to the blower room 120.

The heat exchanger 13 exchanges heat between the refrigerant flowing therein and the outside air, and functions as an evaporator during heating operation and as a condenser during cooling operation. The heat exchanger 13 can be configured as a fin-and-tube heat exchanger, for example. The heat exchanger 13 includes a plurality of heat exchanger tubes 13a and a plurality of fins 13b through which the plurality of heat exchanger tubes 13a are inserted. A refrigerant flows inside the plurality of heat exchanger tubes 13a. The refrigerant exchanges heat with external air via the plurality of fins 13b attached to the plurality of heat transfer tubes 13a. The heat exchanger 13 has a flat plate area and a curved area, and is formed in an L-shape when viewed from above. Note that the shape of the heat exchanger 13 is not limited to the L-shape, and the heat exchanger 13 may be formed in a linear shape when viewed from above.

The propeller fan 14 generates an airflow inside the outdoor unit 100 when driven. Air is sucked into the outdoor unit 100 from the suction port 2a by the propeller fan 14, passes through the heat exchanger 13, and is blown out to the outside.

The compressor 12 and the heat exchanger 13 constitute a refrigeration cycle together with an indoor unit connected to an outdoor unit 100 through an extension pipe. The extension piping and indoor unit are omitted from illustration.

During cooling operation, the gas refrigerant that is compressed by the compressor 12 and becomes high temperature and high pressure flows into the heat exchanger 13, exchanges heat with the air passing outside the heat exchanger 13, and becomes a high pressure liquid refrigerant. It flows out from the heat exchanger 13. The high-pressure liquid refrigerant flowing out from the heat exchanger 13 is depressurized by the expansion valve, flows out from the outdoor unit 100 through the extension pipe, exchanges heat with indoor air in the indoor unit, and then flows into the outdoor unit 100 again. It is sucked into the compressor 12.

During heating operation, the gas refrigerant that has been compressed by the compressor 12 to a high temperature and high pressure flows from the outdoor unit 100 into the indoor unit through an extension pipe, exchanges heat with indoor air, and becomes a high-pressure liquid refrigerant. The high-pressure liquid refrigerant flows from the indoor unit into the outdoor unit 100 again through the extension pipe, is depressurized, and becomes a low-pressure gas-liquid two-phase refrigerant. The low-pressure gas-liquid two-phase refrigerant exchanges heat with outdoor air in the heat exchanger 13, becomes a low-temperature, low-pressure gas refrigerant, and is sucked into the compressor 12 again.

<Sole plate configuration>
FIG. 3 is a perspective view of the bottom plate 6 according to the present embodiment viewed from the front. FIG. 4 is an enlarged perspective view of the bottom plate 6 according to this embodiment. As shown in FIGS. 3 and 4, the bottom plate 6 includes a bottom surface 61 and a wall surface 62 that stands up from the outer peripheral edge of the bottom surface 61. As shown in FIGS. A drainage hole 63 is formed in the bottom plate 6 and extends across the bottom surface 61 and the wall surface 62 on the back side.

The bottom plate 6 constitutes the lower part of the casing of the outdoor unit 100. Components of the outdoor unit 100 are mounted on the upper surface of the bottom plate 6. The bottom plate 6 receives condensed water generated by the heat exchanger 13 placed above on the bottom surface 61. The bottom surface 61 has an uneven shape. The condensed water dripping onto the bottom surface 61 flows on the bottom surface 61 using the downwardly recessed concave drain groove 61a as a drainage path. The drain groove 61a is formed, for example, below the heat exchanger 13 in a shape that follows the shape of the heat exchanger 13.

The drain hole 63 is surrounded by a drain water pool 61b formed between the drain groove 61a and the wall surface 62 on the back side. The drain water reservoir 61b is continuous from the bottom of the drain groove 61a, and is formed in a depressed shape below the bottom of the drain groove 61a. The drain water puddle 61b is the lowest area of the bottom surface 61. The drainage hole 63 is formed at a corner that straddles the bottom surface 61 and the wall surface 62 on the back side and connects the bottom surface 61 and the wall surface 62 on the back side.

The drainage hole 63 is configured by integrating a bottom opening 63a opening into the bottom 61 and a wall opening 63b opening into the wall 62 on the back side. The bottom opening 63a has a U-shape that extends inward from the bottom 61 from the corner where the bottom 61 and the wall 62 are connected. The bottom opening 63a is located at the lowest part of the bottom 61. The wall opening 63b is formed in the wall 62 of the bottom plate 6. The wall opening 63b has a U-shape that is continuous with the bottom opening 63a and extends upward from the corner where the bottom 61 and the wall 62 are connected. If the drain water reservoir 61b is inclined so that the position where the bottom opening 63a is formed is the lowest, water can easily reach the bottom opening 63a.

Since the bottom opening 63a of the drain hole 63 is located at the lowest part of the bottom surface 61, all condensed water is drained from the bottom plate 6. Since the drainage hole 63 is formed by the bottom opening 63a and the wall opening 63b, the drainage path is enlarged compared to the case where a hole formed in the wall surface 62 is used as the drainage path. By providing the bottom opening 63a, the water-filled position of the bottom plate 6 is lower than that in the case where only the hole formed in the wall surface 62 is used as a drainage path, and condensed water is less likely to be retained on the bottom plate 6. The drainage hole 63 is formed, for example, at the center in the left-right direction of the wall surface 62 on the back side.

A plurality of engagement holes 61c are formed in the drain water reservoir 61b on the bottom surface 61. A plurality of engagement holes 62a are formed in the wall surface 62 on the back side. The plurality of engagement holes 61c on the bottom surface 61 and the plurality of engagement holes 62a on the wall surface 62 are holes for attaching the drain base 7 to the bottom plate 6. The drain base 7 will be described later.

<Configuration of the back of the outdoor unit 100>
FIG. 5 is a perspective view showing the back surface of the outdoor unit 100 according to the present embodiment. As shown in FIG. 5, on the back side of the outdoor unit 100, the machine room 110 side is covered by the back panel 2, and the suction port 2a is opened on the blower room 120 side. The back panel 2 may be an L-shaped member when viewed from above that is integrated with the right side panel 3, or may be a separate member from the right side panel 3.

The suction port 2a is an opening that sucks air into the interior of the outdoor unit 100. A heat exchanger 13 is exposed from the suction port 2a. The air sucked into the outdoor unit 100 through the suction port 2a passes through the heat exchanger 13 and is blown out to the outside of the outdoor unit 100 from the air outlet 1a on the front side.

A lower part of the suction port 2a is defined by a wall surface 62 on the back side of the bottom plate 6. A drain base 7 that covers a drain hole 63 formed in a wall surface 62 on the back side is attached to the bottom plate 6 below the suction port 2a.

<Drain base configuration>
FIG. 6 is an enlarged perspective view of the periphery of the drain base 7 according to the present embodiment, viewed from the back. FIG. 7 is an enlarged perspective view of the drain base 7 according to the present embodiment viewed from the back.

As shown in FIGS. 6 and 7, the drain base 7 is fixed to the wall surface 62 on the back side of the bottom plate 6 from the outside. The drain base 7 is provided to drain condensed water flowing out from the drain hole 63 of the bottom plate 6 to a drain hose. The drain base 7 is molded from resin. The drain base 7 is attached to the bottom plate 6 in close contact. The drain base 7 is an L-shaped member in a side view, having a guide surface 71 and a rising surface 72 continuous from the guide surface 71.

The guide surface 71 is a surface along the outer surface of the bottom surface 61 of the bottom plate 6 when the drain base 7 is attached to the bottom plate 6. The guide surface 71 is provided to cover the bottom opening 63a of the drain hole 63 from below and closes the bottom opening 63a. The guide surface 71 is located below the bottom opening 63a of the drain hole 63, and is a surface that receives condensed water that flows from the drain water pool 61b to the drain hole 63 and is drained. The guide surface 71 has a larger area than the bottom opening 63a of the drain hole 63. The guide surface 71 has a structure in which condensed water flowing from the bottom opening 63a does not leak from between the drain base 7 and the bottom plate 6.

The rising surface 72 is a surface along the wall surface 62 of the bottom plate 6 when the drain base 7 is attached to the bottom plate 6, and is a surface that continues from the guide surface 71 and extends upward. A connection hole 7a is formed in the rising surface 72.

The connection hole 7a is a hole through which condensed water flowing out from the drainage hole 63 of the bottom plate 6 and guided to the guide surface 71 is discharged. The lowermost part of the connection hole 7a is in contact with a portion where the rising surface 72 and the guide surface 71 are continuous. The connection hole 7a has a cylindrical shape protruding from the rising surface 72. The condensed water received on the guide surface 71 is drained from the connection hole 7a without remaining on the guide surface 71. The guide surface 71 may have a configuration in which a path from the bottom opening 63a of the drain hole 63 to the connection hole 7a slopes downward. This prevents condensed water from remaining on the guide surface 71.

The rising surface 72 is formed with an engaging protrusion 72 a that projects from the rising surface 72 . The engagement protrusion 72 a of the rising surface 72 is a protrusion that is engaged with an engagement hole 62 a formed in the wall surface 62 of the bottom plate 6 . The engagement protrusion 72a has, for example, a bent tip end shaped like a hook. The engagement protrusion 72a is hooked into the engagement hole 62a. Since the engagement protrusion 72a is made of resin like the drain base 7, the drain base 7 is fixed to the bottom plate 6 by the restoring force of the engagement protrusion 72a.

The guide surface 71 is formed with an engaging protrusion that protrudes from the guide surface 71 . The engagement protrusion on the guide surface 71 may have the same shape as the engagement protrusion 72a formed on the rising surface 72. The engagement protrusion of the guide surface 71 is a protrusion that is engaged with an engagement hole 61c formed in the bottom surface 61 of the bottom plate 6. The engagement protrusion of the guide surface 71 is omitted from illustration.

Since the drain base 7 has the connection hole 7a on the rising surface 72, the condensed water on the bottom plate 6 can be concentrated in the connection hole 7a and drained. The guide surface 71 is preferably curved downward in a shape along the periphery of the connection hole 7a at a portion in contact with the connection hole 7a so that water can easily collect in the connection hole 7a. Condensed water on the guide surface 71 is smoothly discharged from the guide surface 71 through the connection hole 7a.

<Flow of condensed water>
FIG. 8 is a schematic diagram illustrating the flow of condensed water flowing from the bottom plate 6 toward the drain base 7 according to the present embodiment. FIG. 8 shows a cross section of the outdoor unit 100 along the front-rear direction passing through the center of the connection hole 7a. As shown in FIG. 8, the edge of the bottom opening 63a of the drain hole 63 is continuous with the upper surface of the guide surface 71 of the drain base 7. The guide surface 71 of the drain base 7 and the lower part of the connection hole 7a are flush with each other. A drainage path from the guide surface 71 of the drain base 7 toward the connection hole 7a is inclined downward toward the connection hole 7a.

When condensed water is generated in the heat exchanger 13, the condensed water drips onto the bottom plate 6, travels along the drain groove 61a of the bottom surface 61, and reaches the drain hole 63 formed in the drain water reservoir 61b. The condensed water that has reached the drain hole 63 flows from the bottom opening 63 a of the drain hole 63 through the guide surface 71 of the drain base 7 that closes the bottom opening 63 a from below, passes through the wall opening 63 b of the drain hole 63 , and flows through the bottom opening 63 a of the drain base 7 . The connection hole 7a, which is continuous from the guide surface 71, is reached.

Since the drain water puddle 61b on the bottom surface 61 and the edge of the bottom opening 63a of the drain hole 63, the guide surface 71 of the drain base 7, and the lower part of the connection hole 7a of the drain base 7 are flush and continuous, the drain The condensed water in the water pool 61b flows out from the connection hole without stagnation.

Since the bottom opening 63a of the drainage hole 63 is provided at the lowest part of the bottom surface 61, condensed water can be drained from the bottom plate 6 more efficiently than when it is formed only on the wall surface 62 of the bottom plate 6. Ru. By improving the drainage performance from the bottom plate 6, it is possible to prevent blockage of the heat transfer tubes 13a due to freezing of condensed water that may occur when the full water position is above the bottom surface 61, or damage to the fan due to the growth of ice. be done.

The connection hole 7a of the drain base 7 is provided on a rising surface 72 along the wall surface 62 of the bottom plate 6. It can be assigned to the air passage width or the number of heat exchanger stages. Therefore, even in areas where the height of the outdoor unit 100 is restricted due to the installation environment, the required performance of the air conditioner constituted by the outdoor unit 100 is ensured.

<Drain hose connection configuration>
FIG. 9 is an exploded perspective view illustrating connections between the bottom plate 6, drain base 7, socket 8, and drain hose 9 according to the present embodiment. As shown in FIG. 9, a drain base 7 is attached to the bottom plate 6, and a drain hose 9 is connected via a socket 8 attached to the drain base 7. Condensed water dripping onto the bottom plate 6 is discharged from the drain base 7 to the drain hose 9.

When connecting the drain hose 9, first attach the drain base 7 to the bottom plate 6. Specifically, the guide surface 71 of the drain base 7 is aligned with the bottom surface 61 of the bottom plate 6, and the rising surface 72 is aligned with the wall surface 62. Then, the engagement protrusion of the guide surface 71 of the drain base 7 is engaged with the engagement hole 61c of the bottom surface 61 of the bottom plate 6. Further, the engagement protrusion 72a of the rising surface 72 of the drain base 7 is engaged with the engagement hole 62a of the wall surface 62 of the bottom plate 6. When the drain base 7 is attached to the bottom plate 6, the connection hole 7a of the drain base 7 faces the wall opening 63b of the drain hole 63 formed in the bottom plate 6.

Next, the socket 8 is attached to the connection hole 7a of the drain base 7 attached to the bottom plate 6. The socket 8 has an L-shape that, when attached to the drain base 7, protrudes in a direction away from the connection hole 7a of the drain base 7 and then bends in a direction along the casing of the outdoor unit 100. The socket 8 is rotatable around the axial direction of the connection hole 7a of the drain base 7. The socket 8 is attached by being fitted into the connection hole 7a, for example. The socket can be attached to and detached from the connection hole 7a. The connection hole 7a of the drain base 7 is located so as to face the wall opening 63b of the drain hole 63 formed in the bottom plate 6. Since the connection hole 7a of the drain base 7 is provided on the rising surface 72, the socket 8 can be easily attached.

Then, the drain hose 9 is inserted into the socket 8, and the connection of the drain hose 9 is completed. By connecting the drain hose 9 via the socket 8 attached to the drain base 7, the depth size of the outdoor unit 100 is reduced, and the installation space of the outdoor unit 100 is reduced. Since the socket 8 is located on the back side where the suction port 2a is provided, there are special cases where the installation work is limited to the suction port 2a side, such as when the outdoor unit 100 is installed close to a window. The drain hose 9 can be installed even in a suitable installation environment.

By arranging the drainage hole 63 of the bottom plate 6 on the back wall surface 62 where the suction port 2a is provided, the height of the outdoor unit 100 is increased compared to a configuration in which the connection hole 7a is provided on the bottom plate 6. minutes can be assigned to the air channel width or the number of heat exchanger stages. This makes it possible to ensure the required performance of the air conditioner constituted by the outdoor unit 100 even if there are height restrictions due to the installation environment.

According to the outdoor unit 100 according to the present embodiment described above, condensed water flows out from the drain hole 63 formed across the bottom surface 61 and the wall surface 62 of the bottom plate 6, and drains from the drain attached to the bottom plate 6. It flows along the guide surface 71 of the base 7. The condensed water is guided by the guide surface 71 to the connection hole 7a formed in the rising surface 72. The condensed water is then drained toward the drain hose 9 connected to the connection hole 7a. Thereby, the drainage performance of the outdoor unit 100 is improved, and corrosion due to retention of drain water can be effectively prevented. Moreover, by improving drainage performance, damage to the heat exchanger tubes 13a and propeller fan 14 due to freezing of condensed water can be prevented.

Furthermore, by connecting the socket 8 to the connection hole 7a of the drain base 7, it becomes easy to drain condensed water from the drain base 7 to the drain hose 9.

Further, the condensed water passes through a drain groove 61a depressed below the bottom surface 61 and a drain water reservoir 61b depressed below the drain groove 61a, and is discharged from a drain hole 63 formed in the drain water reservoir 61b. Therefore, condensed water is quickly discharged from the bottom plate 6, making it possible to prevent corrosion and improve damage caused by freezing.

In addition, since the drain base 7 in which the connection hole 7a is formed is attached to the back side of the bottom plate 6 located below the suction port 2a, the excess height of the outdoor unit 100 can be adjusted to the air path width or heat exchanger. It can be assigned to the number of stacking stages. As a result, the required performance of the air conditioner configured by the outdoor unit 100 can be ensured even in areas where height restrictions arise due to the installation environment of the outdoor unit 100. In addition, even in a special installation environment where the installation work is limited to the suction port 2a side of the outdoor unit 100, such as when the outdoor unit 100 is installed close to a window, the installation of the outdoor unit 100 is difficult. becomes possible.

Further, the drain base 7 is made of resin, and can be easily attached to the bottom plate 6.

Furthermore, the drain base 7 is formed with an engaging protrusion, and the bottom plate 6 is formed with an engaging hole, so that it can be easily and firmly attached to the bottom plate 6. .

Further, the guide surface 71 of the drain base 7 and the lower part of the connection hole 7a are flush with each other, and the drainage path from the guide surface 71 of the drain base 7 to the connection hole 7a is directed downward toward the connection hole 7a. is inclined to. Therefore, condensed water does not remain on the guide surface 71 and is smoothly discharged from the connection hole 7a.

In addition, the socket 8 can be attached to and detached from the connection hole 7a of the drain base 7, and the bending direction can be changed. can be changed.

1 Front panel, 1a Air outlet, 1b Grill, 2 Back panel, 2a Inlet, 3 Right side panel, 4 Left side panel, 5 Top panel, 6 Bottom plate, 7 Drain base, 7a Connection hole, 8 Socket, 9 Drain Hose, 10 Partition plate, 10a Electrical box, 12 Compressor, 13 Heat exchanger, 13a Heat transfer tube, 13b Fin, 14 Propeller fan, 61 Bottom, 61a Drain groove, 61b Drain puddle, 61c Engagement hole, 62 Wall surface, 62a engagement hole, 63 drainage hole, 63a bottom opening, 63b wall opening, 71 guide surface, 72 rising surface, 72a engagement protrusion, 100 outdoor unit, 110 machine room, 120 blower room.

Claims (8)

a bottom plate having a bottom surface on which a heat exchanger is placed, a wall surface erected from an edge of the bottom surface, and a drainage hole;
A drain base attached to the bottom plate and having a guide surface, a rising surface continuous from the guide surface and extending upward, and a connection hole formed in the rising surface to which a drain hose is connected;
Equipped with
The drainage hole is provided extending from the bottom surface to the wall surface,
The drain base is
the guide surface closes the drainage hole of the bottom surface from below,
the rising surface is along the wall surface,
so that the connection hole faces the drainage hole of the wall surface,
is fixed to the bottom plate from the outside of the bottom plate,
The guide surface of the drain base is
The outdoor unit is curved downward in a shape that follows the circumference of the connection hole . The bottom plate includes
A downwardly recessed drain groove below the heat exchanger;
a drain water puddle that is continuous from the bottom of the drain groove and is depressed below the drain groove;
is formed,
The outdoor unit according to claim 1, wherein the drain hole is formed in the drain water reservoir. a casing including the bottom plate and accommodating the heat exchanger;
The housing is formed with a suction port that sucks air passing through the heat exchanger,
The outdoor unit according to claim 1 or 2, wherein the drain base is attached to a portion of the bottom plate located below the suction port. The outdoor unit according to any one of claims 1 to 3, wherein the drain base is molded with resin. The drain base has an engaging protrusion,
The outdoor unit according to any one of claims 1 to 4, wherein the engagement protrusion engages the engagement hole in the bottom plate. The guide surface is
Continuously flush with the bottom of the connection hole,
The outdoor unit according to any one of claims 1 to 5, wherein the outdoor unit is inclined downward toward the connection hole. further comprising a socket attached to the connection hole,
The outdoor unit according to any one of claims 1 to 6, wherein the drain hose is connected to the connection hole via the socket. The outdoor unit according to claim 7, wherein the socket is detachably attached to the connection hole.

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