JP4862814B2 - Air conditioner outdoor unit - Google Patents

Description

  The present invention relates to an outdoor unit of an air conditioner in which an internal space is partitioned into an air chamber and a machine room by a partition plate, and belongs to the technical field of a ventilation structure in the outdoor unit.

  Conventionally, an outdoor unit of an air conditioner in which an internal space is divided into an air chamber and a machine room by a partition plate is known. In general, in such an outdoor unit, in order to efficiently cool a machine room in which electrical component parts with a large amount of heat are stored, a communication hole that communicates the air chamber and the machine room is provided in the partition plate, The outdoor fan in the air chamber is configured to take air from the machine chamber into the air chamber through the communication hole. By doing so, an air flow can be formed in the machine room, and the electrical component parts in the machine room can be cooled.

Further, since the outdoor unit is often installed outdoors, it is known that rainwater or the like is configured not to enter a machine room or a housing in which electrical component parts are stored. For example, in Patent Document 1, a housing in which electrical component parts are stored is disposed in an air chamber for cooling, and the housing has a sealed structure or a labyrinth structure so that rainwater does not enter the housing. A configuration is disclosed.
JP 2005-326082 A

  By the way, as described above, when a communication hole for ventilation is provided in the partition plate that divides the machine room and the air chamber, rainwater or the like is scattered on the partition plate by the rotation of the outdoor fan in the machine room, and the communication is performed. There is a risk of entering the machine room through the hole. Then, in the case of a general configuration in which electrical component parts are arranged in the machine room, there is a possibility that the electrical component parts break down due to intrusion of rainwater or the like into the machine room.

  The present invention has been made in view of such a point, and an object of the present invention is to provide the partition plate in an outdoor unit of an air conditioner in which an internal space is partitioned into an air chamber and a machine room by a partition plate. By contriving the structure of the ventilation path connected to the communication hole provided in the machine room, it is possible to achieve both a high level of prevention of intrusion of rainwater and the like into the machine room and cooling of electrical component parts in the machine room.

  In order to achieve the above object, in the outdoor unit (2) of the air conditioner (1) according to the present invention, the communication holes (21) in the partition plate (21) partitioning the air chamber (22) and the machine room (23) ( 24) is used as an outlet on the air chamber (22) side, and a ventilation path (27) is formed on the machine chamber (23) side of the partition plate (21), and the inlet of the machine chamber (23) side of the ventilation path (27) is formed. By making the ventilation area a predetermined area with respect to the other ventilation areas on the ventilation path (27), the entrance to the machine room (23) side is prevented while preventing water from entering from the air chamber (22) side. The air flow was not hindered by the draft resistance.

  Specifically, in the first invention, the internal space is divided into an air chamber (22) in which the outdoor fan (8) is accommodated and a machine room in which the electrical component (40) is accommodated by the partition plate (21). (23) The outdoor unit of the air conditioner divided into

The partition plate (21) is provided with a communication hole (24) for communicating the air chamber (22) and the machine room (23), and the machine room of the partition plate (21). On the (23) side, an air passage (27) is formed with the communication hole (24) as an outlet on the air chamber (22) side, and in the machine chamber (23), the partition plate (21) The inlet wall (30a) constituting the machine chamber (23) side inlet of the ventilation path (27) between the machine chamber (23) side inlet and the air chamber (22) on the ventilation path (27) A passage wall portion (36c) that is disposed between the side outlet and that constitutes a crank passage portion (26) that is a part of the ventilation passage (27) and the partition plate (21). The inlet of the machine chamber (23) side has a ventilation area equivalent to the inlet of the crank passage portion (26), and the outlet of the air chamber (22) side of the crank passage portion (26). Equivalent to the ventilation area at the entrance The crank passage portion (26) is formed between the passage wall portion (36c) and the peripheral portion of the communication hole (24) of the partition plate (21) having the above-described ventilation area . A bulging portion (25) bulging inward of the communication hole (24) is provided to a position overlapping the passage wall portion (36c) when viewed from the opening direction of the communication hole (24). Is preferred.

  With this configuration, the ventilation path (27) having the communication hole (24) of the partition plate (21) as the outlet on the air chamber (22) side is connected to the machine room (30) by the partition plate (21) and the inlet wall (30a). 23) Since the side entrance is configured and the partition plate (21) and the passage wall portion (36c) constitute the crank passage portion (26), rainwater and the like are ventilated from the air chamber (22). 27) Even if it enters the inside of the machine room (23), rainwater or the like can be made difficult to enter the machine room (23) by the labyrinth structure including the crank passage (26) and the machine room (23) side entrance.

  And the ventilation area of the machine room (23) side entrance comprised by the said partition plate (21) and an entrance wall part (30a) is comprised by this partition plate (21) and a passage wall part (36c). It is equivalent to the ventilation area of the inlet of the crank passage (26), and the ventilation area of the outlet of the air chamber (22) is equal to or larger than the ventilation area of the inlet of the crank passage (26). Therefore, it is possible to prevent the ventilation resistance at the machine chamber (23) side inlet from becoming larger than the inlet of the crank passage portion (26) and the air chamber (22) side outlet. Thereby, it is possible to prevent the ventilation resistance of the ventilation path (27) from increasing due to the inlet of the machine room (23), and from the machine room (23) to the air chamber (22) via the ventilation path (27). Air can flow smoothly. Therefore, the electrical component (40) in the machine room (23) can be efficiently cooled.

In addition, by doing this, the crank passage portion (26) can be formed on the ventilation path (27), and the communication hole (24) which is the outlet of the air chamber (22) side of the ventilation path (27). A part can be blocked by the bulging part (25), and rainwater in the air chamber (22) can be more reliably prevented from entering the ventilation path (27) through the communication hole (24). be able to.

In the second invention, the internal space is divided into an air chamber (22) in which the outdoor fan (8) is accommodated and a machine room (23) in which the electrical component (40) is accommodated by the partition plate (21). The outdoor unit of the air conditioner divided into

The partition plate (21) is provided with a communication hole (24) for communicating the air chamber (22) and the machine room (23), and the machine room of the partition plate (21). On the (23) side, an air passage (27) is formed with the communication hole (24) as an outlet on the air chamber (22) side, and in the machine chamber (23), the partition plate (21) The inlet wall (30a) constituting the machine chamber (23) side inlet of the ventilation path (27) between the machine chamber (23) side inlet and the air chamber (22) on the ventilation path (27) A passage wall portion (36c) that is disposed between the side outlet and that constitutes a crank passage portion (26) that is a part of the ventilation passage (27) and the partition plate (21). The inlet of the machine chamber (23) side has a ventilation area equivalent to the inlet of the crank passage portion (26), and the outlet of the air chamber (22) side of the crank passage portion (26). Equivalent to the ventilation area at the entrance It is preferable that the communication hole (24) has the above-described ventilation area and is provided to open toward the lower side of the air chamber (22) ( second invention). With this configuration, the ventilation path (27) having the communication hole (24) of the partition plate (21) as the outlet on the air chamber (22) side is connected to the machine room ( 23) Since the side entrance is configured and the partition plate (21) and the passage wall portion (36c) constitute the crank passage portion (26), rainwater and the like are ventilated from the air chamber (22). 27) Even if it enters the inside of the machine room (23), rainwater or the like can be made difficult to enter the machine room (23) by the labyrinth structure including the crank passage (26) and the machine room (23) side entrance.

And the ventilation area of the machine room (23) side entrance comprised by the said partition plate (21) and an entrance wall part (30a) is comprised by this partition plate (21) and a passage wall part (36c). It is equivalent to the ventilation area of the inlet of the crank passage (26), and the ventilation area of the outlet of the air chamber (22) is equal to or larger than the ventilation area of the inlet of the crank passage (26). Therefore, it is possible to prevent the ventilation resistance at the machine chamber (23) side inlet from becoming larger than the inlet of the crank passage portion (26) and the air chamber (22) side outlet. Thereby, it is possible to prevent the ventilation resistance of the ventilation path (27) from increasing due to the inlet of the machine room (23), and from the machine room (23) to the air chamber (22) via the ventilation path (27). Air can flow smoothly. Therefore, the electrical component (40) in the machine room (23) can be efficiently cooled. In addition, this makes it possible to prevent as much as possible rainwater or the like scattered by the rotation of the outdoor fan (8) in the air chamber (22) from directly entering the communication hole (24). That is, since the communication hole (24) opens downward from the air chamber (22), rainwater splashes laterally with respect to the partition plate (21) by the rotation of the outdoor fan (8). And the like can be prevented from directly entering the communication hole (24).

Further, in each configuration as described above, the fin portion (33) protrudes inward of the air chamber (22) below the communication hole (24) of the partition plate (21). Furthermore, it is preferable to apply to a configuration in which a heat sink (31) for cooling the electrical component (40) in the machine room (23) is provided ( third invention). In particular, the fin portion has an opening (21a) formed in the partition plate (21) so that the upper side in the opening (21a) forms the communication hole (24) opening downward. It is preferable to apply to a configuration in which the base portion (32) of the heat sink (31) erected (33) is positioned closer to the machine room (23) than the partition plate (21) ( fourth invention) ).

Thus, in the configuration in which the heat sink (31) for cooling the electrical component (40) in the machine room (23) is disposed below the communication hole (24), the air chamber (22) The water scattered by the outdoor fan (8) in the interior may hit the fin portion (33) of the heat sink (31) and enter the ventilation path (27) from the communication hole (24). By adopting the configuration as in the first and second aspects of the invention, it is possible to prevent intrusion of rainwater and the like into the ventilation passage (27), and rainwater and the like enter the machine room (23) so that electrical component parts (40) can be prevented from being damaged.

  As described above, according to the present invention, the communication space (24) formed in the partition plate (21) that partitions the internal space of the outdoor unit (2) into the air chamber (22) and the machine chamber (23). And the air chamber (22) side outlet of the ventilation path (27), the machine plate (23) side inlet of the ventilation path (27) is configured by the partition plate and the inlet wall (30a), The crank passage part (26) that forms a part of the ventilation path (27) is configured by the partition plate and the passage wall part (36c), so the machine room (from the air chamber (22) side outlet through the ventilation path (27) ( 23) Rainwater can be prevented from entering inside. The ventilation area of the machine chamber (23) side inlet is equivalent to the ventilation area of the inlet of the crank passage portion (26), and the ventilation area of the air chamber (22) side outlet is the crank passage portion ( Since the ventilation area at the entrance of 26) is equal to or greater than the ventilation area, the ventilation resistance at the machine chamber (23) side inlet is prevented from becoming larger than the inlet of the crank passage (26) and the air chamber (22) side outlet. The air can smoothly flow from the machine room (23) to the air chamber (22) through the ventilation path (27). Therefore, with the above-described configuration, while preventing rainwater or the like from entering the machine room (23) from the air chamber (22) through the ventilation path (27), the machine room ( The electrical component (40) in the machine chamber (23) can be efficiently cooled without hindering the flow of air from the air chamber (22) to the air chamber (22).

According to the first aspect of the present invention, the communication hole is formed in the peripheral edge portion of the communication hole (24) of the partition plate (21) so as to constitute the passage wall portion (36c) and the crank passage portion (26). Since the bulging part (25) which bulges inward of (24) is provided, the crank passage part (26) which is a part of the ventilation path (27) can be constituted, and the ventilation It is possible to prevent rainwater or the like from moving to the machine room (23) side in the path (27). Further, by blocking a part of the communication hole (24) by the bulging portion (25), it is possible to prevent rainwater and the like from entering from the communication hole (24), which is the air chamber (22) side outlet, as much as possible. be able to.

Further, according to the second invention, the communication hole (24) is provided so as to open downward from the air chamber (22), so that the outdoor fan (8) is provided in the air chamber (22). Even when rainwater or the like is scattered by the rotation of), the rainwater or the like can be prevented from directly entering the communication hole (24).

Further, according to the third invention, the fin portion (33) protrudes inward of the air chamber (22) below the communicating hole (24) of the partition plate (21). Since the heat sink (31) for cooling the electrical component (40) in the machine room (23) is provided, in this configuration, the rotation of the outdoor fan (8) in the air chamber (22) The rainwater or the like scattered by the air hits the fin portion (33) of the heat sink (31) and easily enters the air passage (27) from the communication hole (24). However, as in the first and second inventions, With the configuration, it is possible to reliably prevent rainwater and the like from entering the machine room (23).

In particular, according to the fourth invention, the heat sink (31) is configured such that the upper side of the opening (21a) formed in the partition plate (21) constitutes the communication hole (24) opening downward. When the base part (33) is positioned closer to the machine room (23) than the partition plate (21) in the opening (21a), rainwater or the like scattered by the rotation of the outdoor fan (8) (31) The fin portion (33) hits the inside of the communication hole (24) more easily. However, by adopting the configuration as in the first and second aspects of the invention, the air passage (27) is interposed. Water can be reliably prevented from entering the machine room (23).

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. It should be noted that the following description of the preferred embodiment is merely illustrative in nature and is not intended to limit the present invention, its application, or its use.

  The present embodiment relates to an air conditioner (1) provided with an outdoor unit (2) according to the present invention. In the air conditioner (1), the outdoor unit (2) is installed outdoors, for example. In the following, the overall configuration of the air conditioner (1) according to the present embodiment will be described first, and then the configuration of the outdoor unit (2) will be described.

<overall structure>
As shown in FIG. 1, the air conditioner (1) includes an outdoor unit (2) and an indoor unit (3). Inside the outdoor unit (2), a compressor (4), an outdoor heat exchanger (5), an expansion valve (6), a four-way switching valve (7), and an outdoor fan (8) are provided. An indoor heat exchanger (12) and an indoor fan (11) are provided inside the indoor unit (3).

  In the outdoor unit (2), the discharge side of the compressor (4) is connected to the first port (P1) of the four-way switching valve (7). The suction side of the compressor (4) is connected to the third port (P3) of the four-way switching valve (7).

  The outdoor heat exchanger (5) is configured as a cross fin type fin-and-tube heat exchanger. One end of the outdoor heat exchanger (5) is connected to the fourth port (P4) of the four-way switching valve (7). On the other hand, the other end of the outdoor heat exchanger (5) is connected to a liquid side shut-off valve (9a).

  The outdoor fan (8) is provided in the vicinity of the outdoor heat exchanger (5). In the outdoor heat exchanger (5), heat is exchanged between the outdoor air flowing by the outdoor fan (8) and the refrigerant flowing through the heat exchanger (5). Between the outdoor heat exchanger (5) and the liquid side closing valve (9a), an expansion valve (6) having a variable opening is provided. The second port (P2) of the four-way selector valve (7) is connected to the gas side shut-off valve (9b).

  The four-way selector valve (7) is in a first state in which the first port (P1) and the second port (P2) communicate with each other and the third port (P3) and the fourth port (P4) communicate with each other. (The state indicated by the solid line in FIG. 1), the second port (P1) and the fourth port (P4) communicate with each other, and the second port (P2) and the third port (P3) communicate with each other. The state (state indicated by a broken line in FIG. 1) can be switched.

  In this air conditioner (1), the heating operation is performed when the four-way switching valve (7) is in the first state, and the cooling operation is performed when the four-way switching valve (7) is in the second state. In the heating operation, a vapor compression refrigeration cycle is performed in which the outdoor heat exchanger (5) functions as an evaporator and the indoor heat exchanger (12) functions as a condenser in the refrigerant circuit shown in FIG. On the other hand, in the cooling operation, a vapor compression refrigeration cycle in which the outdoor heat exchanger (5) functions as a condenser and the indoor heat exchanger (12) functions as an evaporator is performed in the refrigerant circuit shown in FIG.

<Configuration of outdoor unit>
Below, the specific structure of the said outdoor unit (2) is demonstrated based on FIG.

  As shown in FIG. 2 with the cover and piping removed, the outdoor unit (2) is mounted on the base plate (20) with the outdoor heat exchanger (5), outdoor fan (8), compressor (4 ) Etc. are disposed, and the interior is partitioned into an air chamber (22) and a machine chamber (23) by a partition plate (21). The partition plate (21) is erected on the base plate (20) so that the vertical direction is the longitudinal direction, and the central portion in the width direction is on the air chamber (22) side along the longitudinal direction. It is formed to bulge out.

  The outdoor fan (8) is accommodated in the air chamber (22) partitioned by the partition plate (21), and the outdoor heat exchanger is disposed laterally and rearward of the outdoor fan (8). (5) is provided. That is, the outdoor heat exchanger (5) is formed in a substantially L shape in plan view so as to surround the outdoor fan (8). The outdoor fan (8) is configured to introduce the outside air into the air chamber (22) by making the inside of the air chamber (22) have a negative pressure.

  On the other hand, in the machine room (23) partitioned by the partition plate (21), the electrical equipment in which the compressor (4), a four-way switching valve (not shown), and electrical equipment parts (40) are stored. A box (30) and the like are disposed. The electrical component box (30) is attached to the upper part of the partition plate (21).

<Configuration around the partition plate>
Next, the configuration around the partition plate (21) will be described in detail with reference to FIGS.

  As shown in the enlarged view of the upper part of the partition plate (21) in FIG. 3, an opening (21a) is formed in the upper part of the partition plate (21). A heat sink (31) for cooling the electrical component (40) in the product box (30) is disposed. The heat sink (31) is made of a metal member. As shown in FIG. 4, the heat sink (31) has a plate-like base portion (32) and a plurality of fin portions ( 33). The heat sink (31) has a base part (32) thermally connected to an electrical component (40) in the machine room (23) and a fin part (33) in the air chamber (22). It arrange | positions in the opening (21a) of the said partition plate (21) so that it may extend toward the direction. Thereby, the heat generated in the electrical component (40) in the machine room (23) is radiated into the air chamber (22) through the heat sink (31).

  As shown in FIG. 4, the heat sink (31) has a base portion (33) inward of the machine chamber (23) side of the partition plate (21) in the opening (21 a) of the partition plate (21). Is positioned. Thereby, a gap is formed between the heat sink (31) and the partition plate (21). As shown in FIG. 3, the gap between the lower part of the heat sink (31) and the partition plate (21) is closed by the closing plate (34), while the upper part of the heat sink (31) and the partition plate (21) The gap (24) forms a communication hole between the air chamber (22) and the machine chamber (23) (see FIG. 4). That is, by providing such a gap (24), air is passed through the gap (24) from the machine chamber (23) side into the air chamber (22) that is negatively pressured by the outdoor fan (8). Will flow (see white arrows in FIGS. 2 to 4). That is, the said clearance gap (24) comprises the air chamber (22) side exit of the air ventilation path. Further, by forming the gap (24) as described above, the air chamber (22) side outlet is formed so as to open downward between the upper portion of the heat sink (31) and the partition plate (21). Thus, even when rainwater or the like is scattered by rotation of the outdoor fan (8) in the air chamber (22), it is possible to prevent rainwater or the like from directly entering the gap (24).

  As shown in FIG. 4, the upper peripheral edge of the opening (21a) of the partition plate (21) bulges into the gap (24) between the upper portion of the heat sink (31) and the partition plate (21). A bulging portion (25) is formed. The bulging portion (25) bulges up to a position overlapping a lower portion (36c) of a connecting member (36) described later in plan view (viewed from the opening direction of the gap (24)), and the air chamber (22) When rainwater or the like in the interior is scattered by the rotation of the outdoor fan (8), rainwater or the like is prevented from entering directly from the gap (24).

  Here, the heat sink (31) is attached to an attachment member (35) fixed to the peripheral edge of the opening (21a) of the partition plate (21). The mounting member (35) is connected to the peripheral edge of the opening (21a) of the partition plate (21) at the outer peripheral portion thereof, and within the opening (35a) formed in the central portion of the mounting member (35). The base part (33) of the heat sink (31) is disposed on the surface. The upper part of the mounting member (35) supports the upper surface part (30a) of the electrical component box (30). Specifically, the upper surface part (30a) of the electrical component box (30) is connected to the upper part of the mounting member (35) via the connection member (36).

  The connection member (36) is formed in a substantially U shape in a cross-sectional view, and an upper part (36a) extending in the horizontal direction is connected to an end of the upper surface part (30a) of the electrical component box (30). On the other hand, the vertical wall portion (36b) extending in the vertical direction is connected to the mounting member (35). And the lower part (36c) (passage wall part) extended in the horizontal direction of the said connection member (36) is that the front-end | tip part bulges in the opening (21a) of the said partition plate (21) (25 ) And a position that overlaps in plan view. The lower portion (36c) of the connecting member (36) and the bulging portion (25) constitute a crank passage portion (26) extending in a substantially crank shape in a sectional view. That is, a communication passage (27) for communicating the air chamber (22) and the machine chamber (23) is formed on the machine chamber (23) side of the gap (24), and the communication passage (27) Since the crank passage portion (26) constituting the air chamber (22) side extends in a substantially crank shape in a sectional view, even if rainwater in the air chamber (22) enters from the gap (24), Rainwater can be prevented from entering the machine room (23) through the communication passage (27).

  Further, the upper end portion (30a) (entrance wall portion) of the electrical component box (30) connected to the upper portion (36a) of the connection member (36) has an end portion in the communication path (27). It is formed so as to protrude, and constitutes an inlet on the machine chamber (23) side of the communication path (27) with the partition plate (21). Thus, the upper surface part (30a) of the electrical component box (30) constitutes the machine room side entrance of the communication path (27), so that the communication path ( 27) can have a labyrinth structure, and rainwater in the air chamber (22) that has entered the communication passage (27) can be more reliably prevented from entering the machine chamber (23). In addition, the protruding end portion of the upper surface portion (30a) of the electrical component box (30) is bent downward, and is configured so as not to hinder the flow of air from the machine chamber (23) side.

  The gap (24) between the partition plate (21) and the heat sink (31), the gap between the partition plate (21) and the lower part (36c) of the connection member (36), and the partition plate (21) and the above The gaps between the electrical component box (30) and the upper surface portion (30a) have shapes as indicated by hatching in FIGS. Among these gaps, the area X of the gap between the partition plate (21) and the upper surface part (30a) of the electrical component box (30) (the ventilation area at the machine room side entrance, the hatched part in FIG. 5A) is The area Y of the gap between the partition plate (21) and the lower part (36c) of the connecting member (36) (the ventilation area at the inlet of the crank passage, the hatched portion in FIG. 5B) is the same area. Yes. Thus, as described above, when the outdoor fan (8) creates a negative pressure in the air chamber (22) and air flows from the machine chamber (23) to the air chamber (22), the portion of the area X Can prevent large ventilation resistance. That is, the airflow resistance in the area X is equal to the airflow resistance in the area Y, so that it is possible to prevent the air flow from being restricted in the area X.

  Further, the area Z of the gap (24) between the partition plate (21) and the heat sink (31) (the ventilation area of the air chamber side outlet, the hatched portion in FIG. 5C) is equivalent to the above-described areas X and Y. Or more. By doing so, the area Z can be prevented from blocking air flow from the machine chamber (23) to the air chamber (22) due to a large ventilation resistance. If the area Z is equal to the areas X and Y, rainwater in the air chamber (22) enters from the area Z while preventing an increase in ventilation resistance in the area Z. Can be prevented.

  Here, in the present embodiment, that the areas are equal includes not only the case where the areas are the same, but also the case where the areas vary to such an extent that the ventilation is not affected.

-Effect of the embodiment-
As described above, in this embodiment, in the upper part of the partition plate (21) that partitions the interior of the outdoor unit (2) into the air chamber (22) and the machine room (23), the air chamber (22) and the machine room ( 23) and a gap (24) that forms a communication hole that communicates with 23), and a crank passage portion (26) that is substantially crank-shaped in cross-section and covers a part of the gap (24). By providing the lower part (36c) of the connecting member (36), rainwater and the like in the air chamber (22) scattered by the rotation of the outdoor fan (8) can be transferred to the machine room (27) via the communication path (27). 23) Prevents intrusion to the side.

  Moreover, the top surface portion (30a) of the electrical component box (30) connected to the mounting member (35) of the heat sink (31) via the connection member (36) has a tip portion within the communication path (27). The machine room (23) of the communication path (27) is formed by a gap between the upper surface part (30a) of the electrical component box (30) and the partition plate (21). An entrance on the side is configured, and the gap can also prevent rainwater or the like in the air chamber (22) from entering the machine chamber (23) through the communication path (27).

  Moreover, since the said clearance gap (24) which comprises an air chamber (22) side exit is provided so that it may open toward the downward direction of an air chamber (22), in this air chamber (22) outdoor fan ( Even when rain water or the like is scattered by the rotation of 8), it is possible to prevent rain water or the like from entering directly into the gap (24).

  The area X of the gap between the partition plate (21) and the upper surface portion of the electrical component box (30) is the area Y of the gap between the partition plate (21) and the lower part (36c) of the connection member (36). Therefore, the area X can prevent the air flow in the communication path (27) from being hindered. The gap (24) has an area Z equal to the areas X and Y by the bulging part (25) that bulges into the gap from the upper peripheral edge of the opening (21a) of the partition plate (21). Since it becomes more than that, it can prevent that the flow of air is inhibited by this clearance gap (24). In particular, by making the area Z of the gap (24) equal to the areas X and Y, the flow of air in the communication path (27) is not hindered, and rainwater from the gap (24), etc. Can be prevented as much as possible.

  Furthermore, in the configuration of the present embodiment, the fin portion (33) of the heat sink (31) is located below the gap (24) that forms the air chamber (22) side outlet of the communication passage (27). When rainwater or the like is scattered by rotation of the outdoor fan (8) in the air chamber (22), the scattered rainwater or the like hits the fin (33) and enters the communication passage (27) from the gap (24). However, it is possible to reliably prevent rainwater and the like from entering the machine room (23) through the communication path (27) by using the above-described configurations.

<< Other Embodiments >>
The above embodiment may be configured as follows.

  In the embodiment described above, the partition plate (21) that partitions the internal space of the outdoor unit (2) into the air chamber (22) and the machine chamber (23) has a central portion in the width direction on the air chamber (22) side. Although it is configured to swell, the shape is not limited to this, and any shape may be used as long as the internal space of the outdoor unit (2) can be partitioned.

  Moreover, in the said embodiment, the heat sink for cooling the electrical component (40) in a machine room (23) below the clearance gap (24) which comprises the air chamber (22) side exit of a communicating path (27). Although (31) is provided, the present invention is not limited to this, and the present invention may be applied to a configuration in which the heat sink (31) is provided in another place or the heat sink (31) is not provided.

  As described above, the present invention is particularly useful for an outdoor unit of an air conditioner in which an internal space is partitioned into an air chamber and a machine room by a partition plate.

FIG. 1 is a piping system diagram showing a schematic configuration of an air conditioner including an outdoor unit according to an embodiment of the present invention. FIG. 2 is a perspective view showing a state in which the cover and piping of the outdoor unit are removed. FIG. 3 is a perspective view showing the structure of the upper part of the partition plate. 4 is a cross-sectional view taken along line IV-IV in FIG. 5 is a cross-sectional view taken along line (A) Va-Va, (B) a cross-sectional view taken along line Vb-Vb, and (C) a cross-sectional view taken along line Vc-Vc in FIG.

1 Air conditioner
2 Outdoor unit
8 Outdoor fan
21 Partition plate
22 Air chamber
23 Machine room
24 Clearance (communication hole)
25 bulge
26 Crank passage
27 Communication path (ventilation path)
30 Electrical component box
30a Top surface (entrance wall)
31 heat sink
32 Base part
33 Fin
36 Connecting material
36c Lower part (passage wall)
40 Electrical components

Claims (4)

An air conditioner in which the internal space is divided into an air chamber (22) in which the outdoor fan (8) is accommodated and a machine room (23) in which the electrical component (40) is accommodated by the partition plate (21). Outdoor unit,
The partition plate (21) is provided with a communication hole (24) for communicating the air chamber (22) and the machine chamber (23), and the partition chamber (21) has a machine chamber (23 ) Side is formed with a ventilation path (27) with the communication hole (24) as an outlet on the air chamber (22) side,
In the machine room (23), an inlet wall (30a) that constitutes the machine room (23) side entrance of the ventilation path (27) between the partition plate (21) and the ventilation path (27 ) Between the machine room (23) side inlet and the air chamber (22) side outlet above, and a crank-shaped part of the ventilation path (27) between the partition plate (21) A passage wall portion (36c) constituting the passage portion (26), and
The machine room (23) side inlet has a ventilation area equivalent to the inlet of the crank passage (26),
The air chamber (22) side outlet has a ventilation area equal to or greater than the ventilation area of the inlet of the crank passage (26), and the peripheral edge of the communication hole (24) of the partition plate (21) The communication hole so as to form the crank passage portion (26) with the passage wall portion (36c) to a position overlapping the passage wall portion (36c) when viewed from the opening direction of the communication hole (24). An outdoor unit for an air conditioner, comprising a bulging portion (25) bulging inward of (24). An air conditioner in which the internal space is divided into an air chamber (22) in which the outdoor fan (8) is accommodated and a machine room (23) in which the electrical component (40) is accommodated by the partition plate (21). Outdoor unit,
The partition plate (21) is provided with a communication hole (24) for communicating the air chamber (22) and the machine chamber (23), and the partition chamber (21) has a machine chamber (23 ) Side is formed with a ventilation path (27) with the communication hole (24) as an outlet on the air chamber (22) side,
In the machine room (23), an inlet wall (30a) that constitutes the machine room (23) side entrance of the ventilation path (27) between the partition plate (21) and the ventilation path (27 ) Between the machine room (23) side inlet and the air chamber (22) side outlet above, and a crank-shaped part of the ventilation path (27) between the partition plate (21) A passage wall portion (36c) constituting the passage portion (26), and
The machine room (23) side inlet has a ventilation area equivalent to the inlet of the crank passage (26),
The outlet on the air chamber (22) side has a ventilation area equal to or greater than the ventilation area of the inlet of the crank passage portion (26), and the communication hole (24) faces downward of the air chamber (22). An outdoor unit for an air conditioner, wherein the outdoor unit is provided to open. In claim 1 or 2 ,
In the machine chamber (23), the fin portion (33) protrudes inward of the air chamber (22) below the communication hole (24) of the partition plate (21). An outdoor unit for an air conditioner, comprising a heat sink (31) for cooling the electrical component (40). In claim 3 ,
The partition plate (21) has an opening (21a),
The heat sink (31) has a base portion (32) on which the fin portion (33) is erected so as to constitute the communication hole (24) whose upper side in the opening (21a) opens downward. Is positioned closer to the machine room (23) than the partition plate (21).

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