JP6451752B2 - Indoor unit of air conditioner - Google Patents

Description

  The present invention relates to an indoor unit of an air conditioner.

  Conventionally, an indoor unit of an air conditioner including a casing in which air flows, a heat exchanger provided in the casing, and a fan provided below the heat exchanger in the casing is known. (For example, Patent Document 1). In the indoor unit of the same document, an air inlet is formed in the top plate of the casing, an air outlet is formed in the bottom plate of the casing, and an air flow from the air inlet to the air outlet by the fan (that is, the casing) An air flow that flows downward in the interior) is generated. The heat exchanger is configured to exchange heat between air flowing in the casing and fluid (for example, refrigerant) flowing in the casing.

Japanese Patent Laying-Open No. 2015-102257

  By the way, when performing a cooling operation, for example, moisture contained in room air may be condensed in the heat exchanger to generate drain water. Most of the drain water flows into a drain pan provided directly below the heat exchanger and then discharged out of the casing. A part of the drain water is scattered downward together with the air passing through the heat exchanger.

  On the other hand, a second drain pan for receiving drain water that has not flowed into the drain pan (that is, the first drain pan) described above is provided below the heat exchanger and the first drain pan, and the drain water is further guided to the second drain pan. It is conceivable to provide a drain water guide member. As a result, the drain water that has flowed out below the first drain pan can be guided to the second drain pan by the drain water guide member, and discharged out of the casing through the second drain pan.

  However, the second drain pan provided below the heat exchanger is located relatively close to the fan also provided below the heat exchanger due to space limitations in the casing. For this reason, conventionally, in order to prevent the drain water in the second drain pan from being rolled up by the air flow of the fan, a drain pan cover that covers the opening of the second drain pan has been provided. Further, the drain water is configured to flow into the second drain pan through the through hole formed in the drain pan cover. However, since the drain pan cover has a certain thickness, the drain water flowing on the drain water guide member stays at the edge of the drain pan cover, and smooth drainage is prevented. And when drain water accumulates, there exists a possibility that drain water may be rolled up with a fan and blown off with air.

  The present invention has been made in view of such a point, and an object of the present invention is to smoothly drain water through the drain pan in an indoor unit of an air conditioner including a drain pan whose opening is covered with a drain pan cover. Is to enable proper discharge.

  The first invention is directed to the indoor unit (10) of the air conditioner (1). The indoor unit (10) includes a casing (11) through which air flows, a heat exchanger (20) provided in the casing (11) for exchanging heat between the air and a fluid flowing through the inside, and the casing A drain pan (22) provided below the heat exchanger (20) in (11) and opened upward to receive drain water generated in the heat exchanger (20), and an opening of the drain pan (22) A drain water guide member (24) having an upper surface (24a) extending obliquely upward from the edge (22a) outward, and provided between the heat exchanger (20) and the drain pan (22). It has a fan (25) and a drain pan cover (30) that covers the opening of the drain pan (22), and the drain water passes between the drain water guide member (24) and the drain pan cover (30). A gap (G) that can conduct water is formed. There.

  In the first aspect of the invention, the drain water scattered from the heat exchanger (20) falls onto the upper surface (24a) of the drain water guide member (24), and on the upper surface (24a) of the drain water guide member (24). It is guided to the drain pan (22). And the drain water guided toward the drain pan (22) flows into the drain pan (22) smoothly through the water guide gap (G), while hardly remaining at the edge of the drain pan cover (30). . The drain water in the drain pan (22) is hardly wound up by the air flow generated by the fan (25) because the opening of the drain pan (22) is covered by the drain pan cover (30). The drain water flowing into the drain pan (22) is then discharged out of the casing (11).

  In a second aspect based on the first aspect, the edge (30a) of the drain pan cover (30) covers the edge (24b) on the drain pan (22) side of the drain water guide member (24). The water guide gap (G) is formed between the edge (30a) of the drain pan cover (30) and the drain water guide member (24).

  In the second aspect of the invention, the opening of the drain pan (22) is entirely covered by the drain pan cover (30). For this reason, it is suppressed more reliably that the drain water in a drain pan (22) is wound up by the air flow which a fan (25) produces.

  According to a third aspect, in the second aspect, the drain water guide member (24) and the drain pan cover (30) are provided between the drain water guide member (24) and the drain pan cover (30). The spacer (31) which forms the said gap | interval (G) for water conveyance between these is characterized by the above-mentioned.

  In the third aspect of the present invention, the water guide gap (G) is easily formed by the spacer (31).

  In a fourth aspect based on the third aspect, the spacer (31) is provided on the drain pan cover (30).

  In the fourth aspect of the invention, since the spacer (31) is provided in the drain pan cover (30), it is sufficient to change the design of only the drain pan cover (30) in order to form the water guide gap (G).

  In a fifth aspect based on the fourth aspect, the drain pan (22) and the drain pan cover (30) have an elongated shape extending in a predetermined direction, and the spacer (31) includes the drain pan cover (30 ) At both ends and an intermediate part in the longitudinal direction, and fixed to the drain water guide member (24).

  In the fifth invention, since each spacer (31) is fixed to the drain water guide member (24), the elongated drain pan cover (30) is bent and deformed by the influence of the air flow generated by the fan (25). Is deterred. At the same time, the portion where the spacer (31) is not provided in the space between the drain water guide member (24) and the drain pan cover (30) serves as a water guide gap (G). It is also secured.

  According to a sixth invention, in any one of the first to fifth inventions, the fan (25) includes a fan case (26) in which a suction port (26a) is formed on a side surface, and the fan case ( 26), and the indoor unit (10) of the air conditioner (1) is located below the inlet (26a) of the fan (25) and the drain. A fan partition plate (32) disposed above the water guide member (24) and covering a portion of the drain water guide member (24) located on the side of the inlet (26a) of the fan (25) It is characterized by having.

  In the sixth aspect of the invention, since the fan partition plate (32) is provided between the drain guide member (24) and the suction port (26a) of the fan (25), the fan partition plate ( In the part covered with 32), the turbulence of the airflow is reduced and the amount of drain water wound up by the fan (25) is reduced. Further, even if the drain water is rolled up, the drain water hits the lower surface of the fan partition plate (32), so that it is difficult to be sucked into the fan (25). Thus, in 6th invention, it is suppressed that drain water is inhaled by the suction inlet (26a) of a fan (25).

  In a seventh aspect based on the sixth aspect, the suction port (26a) of the fan (25) is formed in a circular shape, and the fan partition plate (32) along the side surface of the fan (25) is formed. The length (W) is shorter than the diameter (D) of the suction port (26a).

  In the seventh invention, since the length (W) of the fan partition plate (32) is shorter than the diameter (D) of the suction port (26a), the heat exchanger (20) is placed on the upper surface of the fan partition plate (32). It is difficult for the drain water to fall directly from and stay. Therefore, it is suppressed that drain water accumulates on the upper surface of the fan partition plate (32) and is sucked into the suction port (26a) of the fan (25).

  According to the present invention, since drain water smoothly flows into the drain pan (22) through the water guide gap (G), the drain water is prevented from staying at the edge (30a) of the drain pan cover (30). The drain water can be smoothly discharged through the drain pan (22). Thereby, it is possible to prevent the drain water from being wound around the fan (25) and blown out of the casing (11).

  Moreover, according to the said 2nd invention, it can suppress more reliably that the drain water in a drain pan (22) is wound up with a fan (25).

  Moreover, according to the said 3rd invention, the clearance gap (G) can be easily formed by the spacer (31).

  Further, according to the fourth aspect of the invention, since it is sufficient to change the design of the drain pan cover (30) from the conventional one in order to form the water guide gap (G), the indoor unit (10) of the present invention is provided. It can be manufactured at a low cost.

  Further, according to the fifth aspect, it is possible to prevent the slender drain pan cover (30) from being bent and deformed by the air flow generated by the fan (25), and at the same time to ensure smooth drain water discharge.

  Moreover, according to the said 6th invention, it can suppress that the drain water which flows on a drain water guide member (24) toward a drain pan (22) is sucked into the suction inlet (26a) of a fan (25). it can.

  Moreover, according to the said 7th invention, it can suppress that drain water accumulates on the upper surface of a fan partition plate (32), and is sucked in from the suction inlet (26a) of a fan (25).

Drawing 1 is a figure showing the air harmony device of an embodiment roughly. FIG. 2 is a right side view schematically showing the indoor unit of the embodiment. FIG. 3 is a front view schematically showing the indoor unit of the embodiment. FIG. 4 is a detailed cross-sectional view showing the periphery of the drain pan cover and the second drain pan. FIG. 5 is a schematic perspective view of the drain pan cover as viewed from below. FIG. 6 is a perspective sectional view showing a peripheral portion of the fan partition plate. FIG. 7 is a cross-sectional view showing the periphery of the fan partition plate as viewed from the right. FIG. 8 is a detailed cross-sectional view showing a peripheral portion of a drain pan cover and a second drain pan according to a modification.

  Embodiments of the present invention will be described in detail with reference to the drawings. The following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use.

-Configuration of air conditioner-
As shown in FIG. 1, the air conditioner (1) of the present embodiment is dedicated to cooling that cools the computer room (S11) in which the computer (7) is installed. However, the air conditioner (1) may be another type of air conditioner that can selectively perform cooling and heating. The air conditioner (1) includes an outdoor unit (2) and an indoor unit (10). The outdoor unit (2) and the indoor unit (10) are connected to each other via the refrigerant pipe (3). The outdoor unit (2) is installed outdoors, and the indoor unit (10) is installed in an indoor air conditioner room (S12).

  The computer room (S11) and the air conditioner room (S12) are separated from each other by a partition (4). Under the floor of the computer room (S11) and the air conditioner room (S12), an underfloor space (S14) is formed, and the floor of the computer room (S11) has a plurality of air inlets (6). ing. A ceiling space (S13) is formed in the back of the ceiling of the computer room (S11), and a plurality of exhaust ports (5) are provided in the ceiling of the computer room (S11). The ceiling space (S13) communicates with the air conditioner room (S12).

-Configuration of indoor unit-
The indoor unit (10) of the air conditioner (1) of this embodiment is connected to a refrigerant circuit (not shown) that performs a vapor compression refrigeration cycle. For example, as described above, the computer room (S11 ) Used for air conditioning. However, the use of the indoor unit (10) is not limited to this. The indoor unit (10) includes a casing (11), a heat exchanger (20), a first drain pan (21), a second drain pan (22), a partition plate (24), and a fan (25). A duct member (28), a drain pan cover (30), and a fan partition plate (32). For convenience of explanation, the left side in FIG. 2 is “front side”, the right side is “rear side”, the front side is “right side”, and the back side is “left side”.

  As shown in FIGS. 2 and 3, the casing (11) is formed in a substantially vertically long rectangular parallelepiped box shape, and includes a top plate (12), a bottom plate (13), a top plate (12), and a bottom plate (13 And a side plate (14) for connecting. The casing (11) has an air inlet (12a) for sucking room air into the top plate (12) and an air outlet (13a) for blowing out cooled air to the bottom plate (13). Yes. The side plate (14) includes a front side plate (14a), a rear side plate (14b), a right side plate (14c), and a left side plate (14d) each formed in a substantially rectangular plate shape. In FIGS. 2 and 3, the right side plate (14c) and the front side plate (14a) are omitted so that the arrangement of the members in the casing (11) can be easily understood.

  Two heat exchangers (20) are provided below the air inlet (12a) in the casing (11). For example, as shown in FIG. 2, the two heat exchangers (20) are arranged in a V shape so that the distance between the two heat exchangers (20) increases toward the top in a side view. The number and arrangement of the heat exchangers (20) are not limited to this. The heat exchanger (20) heat-exchanges the air flowing through the casing (11) and the fluid flowing inside the casing (11) (in this embodiment, the refrigerant circulating in the refrigerant circuit) through the air inlet (12a). It is configured. As shown in FIG. 3, the heat exchanger (20) extends substantially over the entire length in the casing (11) in the left-right direction.

  A 1st drain pan (21) is a bowl-shaped member comprised so that the lower end part of two heat exchangers (20) might be covered from the lower side. As shown in FIGS. 2 and 3, the first drain pan (21) covers the lower end portion of the heat exchanger (20) from the lower side substantially over the entire length in the left-right direction. For this reason, the 1st drain pan (21) can receive the drain water which arises in a heat exchanger (20). The drain water that has flowed into the first drain pan (21) is guided to the second drain pan (22) via a first drain hose (not shown). The indoor unit (10) is configured so that drain water flowing into the first drain pan (21) is directly discharged out of the casing (11) without passing through the second drain pan (22). Also good.

  The second drain pan (22) is a bowl-shaped member provided below the heat exchanger (20) and directly below the first drain pan (21). As shown in FIGS. 2 and 3, the second drain pan (22) is opened upward and extends substantially over the entire length in the casing (11) in a predetermined direction, that is, in the left-right direction. That is, the 2nd drain pan (22) is arrange | positioned in the center part of the front-back direction of a casing (11) so that the inside of a casing (11) may be crossed to the left-right direction.

  Drain water flowing on the partition plate (24) after flowing in the heat exchanger (20) flows into the second drain pan (22). A second drain hose (not shown) for discharging drain water in the second drain pan (22) to the outside of the casing (11) is connected to the bottom of the central portion in the longitudinal direction of the second drain pan (22). Hose connection pipe (23) is provided. The second drain pan (22) also has drain openings (22b) that can be connected to the second drain hose at both the left and right ends, so that the user's request or the indoor unit (10) can be installed. Accordingly, the second drainage hose can be selected to connect to either the hose connection pipe (23) or the drainage opening (22b). The second drain pan (22) constitutes a drain pan.

  The partition plate (24) is provided below the heat exchanger (20) in the casing. The partition plate (24) is a plate-like member having an upper surface (24a) extending obliquely upward from the opening edge (22a) of the second drain pan (22) toward the outside. One partition plate (24) extends obliquely upward from the front opening edge (22a) of the second drain pan (22) toward the front plate (14a). The other partition plate (24) extends obliquely upward from the rear opening edge (22a) of the second drain pan (22) toward the rear plate (14b).

  The partition plate (24) partitions the internal space of the casing (11) into an upper space (S1) and a lower space (S2). A heat exchanger (20), a first drain pan (21), a fan (25), a motor (not shown), etc. are arranged in the upper space (S1), and an electrical unit not shown in the lower space (S2) Is arranged. The drain water splashed from the heat exchanger (20) falls into the partition plate (24) without flowing into the first drain pan (21). As shown in FIGS. 2 and 4, the partition plate (24) is inclined so as to become lower toward the center in the casing (11) in a side view. Thus, the partition plate (24) is configured to guide the drain water to the second drain pan (22). The partition plate (24) constitutes a drain water guide member.

  The fan (25) is provided between the heat exchanger (20) and the second drain pan (22) in the casing (11). Specifically, as shown in FIG. 3, two fans (25) are provided side by side at a substantially central portion in the vertical direction of the internal space of the casing (11). The number and arrangement of the fans (25) are not limited to this. As shown in FIGS. 2, 3 and 6, the fan (25) includes a fan case (26) in which circular suction ports (26a) are formed on the side surfaces (left and right side surfaces), and the fan case (26). And an impeller (27) housed in the housing. As shown in FIG. 3, the fan (25) is a so-called sirocco fan configured to suck air from the suction port (26a) and blow it downward as the impeller (27) rotates. The fan (25) is fixedly supported by a support member (not shown). The impeller (27) of the fan (25) is driven by a motor (not shown).

  The duct member (28) is a rectangular cylindrical member extending vertically, and its inflow end (upper end) is connected to the air outlet of the fan (25), and its outflow end (lower end) is the casing (11). ) Is connected to the air outlet (13a). That is, the air blown out from the fan (25) goes out of the casing (11) through the duct member (28) through the air outlet (13a).

  As shown in FIGS. 3 and 5, the drain pan cover (30) is an elongated and substantially rectangular plate-like member extending in a predetermined direction, that is, in the left-right direction, and covers the opening of the second drain pan (22). ing. That is, the drain pan cover (30) is provided directly below the first drain pan (21) (see FIG. 2). As shown in FIG. 4, the edge part (30a) (namely, width direction both ends) of the drain pan cover (30) inclines so that it may become high as it goes to the width direction outer side. The edge (30a) of the drain pan cover (30) covers the edge (24b) of the partition plate (24) on the second drain pan (22) side. An intermediate portion in the width direction of the drain pan cover (30) is formed in a substantially horizontal flat plate shape.

  As shown in FIG. 5, the drain pan cover (30) is provided with spacers (31) at both end portions and a central portion in the longitudinal direction. In FIG. 4, the spacer (31) is not shown so that the water guide gap (G) can be easily understood. Specifically, two spacers (31) are provided at one end of the drain pan cover (30) in the longitudinal direction, one spacer (31) is provided at the center in the longitudinal direction, and two spacers are provided at the other end in the longitudinal direction. A spacer (31) is integrally formed with the drain pan cover (30). Each spacer (31) may be formed separately from the drain pan cover (30) and attached to the drain pan cover (30). The drain pan cover (30) is screwed and fixed to the partition plate (24) through, for example, a hole formed in the region of the spacer (31). In addition, the fixation aspect to the partition plate (24) of a drain pan cover (30) is not restricted to this.

  Between the partition plate (24) and the drain pan cover (30), a spacer (31) forms a water guide gap (G) through which drain water flowing on the partition plate (24) can pass. (The flow of drain water is indicated by an arrow in FIG. 4). In addition, a plurality of circular through holes (30b) (in this example, six through holes (30b)) are formed at predetermined intervals in the longitudinal direction at the center in the width direction of the drain pan cover (30). Yes. The drain water present on the drain pan cover (30) flows into the second drain pan (22) through these through holes (30b).

  As shown in FIGS. 2 and 3, the fan partition plate (32) is arranged on both left and right sides of the fan (25), that is, on the left side of the left fan (25), between both fans (25), and on the right fan ( 25) are plate-like members respectively provided on the right side. As shown in FIGS. 6 and 7, the fan partition plate (32) is provided between the suction port (26a) of the fan (25) and the partition plate (24). Of these, the part located on the side of the inlet (26a) of the fan (25) is covered. Further, the upper surface of the fan partition plate (32) is inclined so as to go downward as it is away from the second drain pan (22).

  Here, the drain water flowing on the partition plate (24) may be sucked together with air from the suction port (26a) formed on the side surface of the fan (25). When the drain water is sucked into the fan (25), the drain water flows out of the casing (11) together with the blown air.

  In contrast, each fan partition plate (32) is provided between the suction port (26a) of the fan (25) and the partition plate (24), and the side of the suction port (26a) in the partition plate (24). The part located in the direction is covered. Thereby, even when the drain water flowing on the partition plate (24) reaches below the suction port (26a), the drain water is prevented from being sucked into the suction port (26a). Each fan partition plate (32) is disposed directly under the suction port (26a) of the fan (25) in a side view. Moreover, as shown in FIG. 7, the width (W) of each fan partition plate (32) is shorter than the diameter (D) of the inlet (26a) of the fan (25).

-Driving action-
Next, the operation of the indoor unit (10) will be described.

<Cooling operation>
The air conditioner (1) including the refrigerant circuit to which the indoor unit (10) is connected is configured to perform a cooling operation. In this cooling operation, electric power is supplied to a motor (not shown) to drive the fan (25).

  When the air conditioner (1) performs cooling, the conditioned air (cooled air) blown out from the indoor unit (10) is converted into an underfloor space (S14) as indicated by arrows in FIG. ) Is supplied from the air supply port (6) to the computer room (S11). Thereby, the computer room (S11) is cooled. On the other hand, the air in the computer room (S11) flows into the ceiling space (S13) from an exhaust port (5) provided in the ceiling, for example, and is then sucked into the indoor unit (10). The air sucked into the indoor unit (10) is cooled when flowing through the heat exchanger (20) and blown out from the indoor unit (10).

  In the cooling operation, the heat exchanger (20) functions as an evaporator. The heat exchanger (20) exchanges heat between the low-pressure gas-liquid two-phase refrigerant decompressed by an expansion mechanism (not shown) and the air flowing in the casing (11). Specifically, in the heat exchanger (20), the air is cooled by transferring heat from the air in the casing (11) to the low-pressure gas-liquid two-phase refrigerant. The cooled air is supplied from the air outlet (13a) of the casing (11) to the computer room (S11) through the underfloor space (S14).

<Drain water discharge>
In the cooling operation described above, air is cooled in the heat exchanger (20), whereby moisture contained in the air is condensed and drain water is generated. Most of the drain water generated in the heat exchanger (20) flows into the first drain pan (21) through the surface of the heat exchanger (20), and passes through the first drain hose to the second drain pan (22 ) The drain water flowing into the second drain pan (22) is discharged out of the casing (11) via the second drain hose.

  On the other hand, part of the drain water generated in the heat exchanger (20) is scattered into the internal space of the casing (11) without flowing into the first drain pan (21) due to the influence of the air flow generated by the fan (25). To do. The drain water scattered in the internal space of the casing (11) falls on the side plate (14) of the casing (11) or directly onto the partition plate (24). The drain water that has fallen on the partition plate (24) flows on the partition plate (24) toward the second drain pan (22).

  Here, a drain pan cover (30) that covers the opening of the second drain pan (22) is provided above the second drain pan (22). This drain pan cover (30) is provided conventionally as described at the beginning, and prevents the drain water flowing on the partition plate (24) from smoothly flowing into the second drain pan (22). It was. On the other hand, in this embodiment, by providing a spacer (31) between the drain pan cover (30) and the partition plate (24), drain water is provided between the drain pan cover (30) and the partition plate (24). The gap for water conveyance (G) through which can pass is formed. For this reason, the drain water flowing on the partition plate (24) flows along the upper surface (24a) as it is, passes through the water guide gap (G), and smoothly flows into the second drain pan (22). The drain water flowing into the second drain pan (22) is discharged out of the casing (11) via the second drain hose.

  In addition, due to spatial restrictions in the casing (11), the fan (25) and the partition plate (24) provided below the heat exchanger (20) are arranged relatively close to each other. For this reason, the drain water flowing on the partition plate (24) may be sucked together with the air from the suction port (26a) of the fan (25) and blown out of the casing (11) together with the air. . On the other hand, in this embodiment, the drain water flowing through the partition plate (24) is sucked into the suction port (26a) between the suction port (26a) of the fan (25) and the partition plate (24). The fan partition plate (32) to suppress is provided. For this reason, the drain water flowing on the partition plate (24) is hardly sucked into the suction port (26a) of the fan (25), and almost all the drain water flowing on the partition plate (24) is second. It flows into the drain pan (22). The drain water flowing into the second drain pan (22) is discharged out of the casing (11) via the second drain hose.

-Effect of the embodiment-
In the above embodiment, the spacer (31) forms a water guide gap (G) through which drain water can pass between the drain pan cover (30) and the partition plate (24). This prevents the drain water flowing on the partition plate (24) from staying at the edge (30a) of the drain pan cover (30) and smoothly drains the drain water through the second drain pan (22). Can be realized. Therefore, it is possible to prevent the drain water from collecting on the edge of the drain pan cover (30) and being wound up by the fan (25) and being blown out of the casing (11) together with the conditioned air. Further, the water guide gap (G) can be easily formed by the spacer (31).

  In the above embodiment, since the edge (30a) of the drain pan cover (30) covers the edge (24b) on the second drain pan (22) side of the partition plate (24), the second drain pan (22) The entire opening is covered with a drain pan cover (30). Thereby, it can suppress more reliably that the drain water in a 2nd drain pan (22) is wound up by the air flow which a fan (25) produces.

  In the above embodiment, since the spacer (31) is integrally formed with the drain pan cover (30), the drain pan cover (30) is used as a conventional spacer (31) in order to form the water guide gap (G). It is only necessary to change the design from those without. Therefore, the indoor unit (10) that exhibits the effects of the present embodiment can be manufactured at low cost.

  Moreover, in the said embodiment, the spacer (31) is each provided in the both ends and center part of the longitudinal direction of the drain pan cover (30), and each spacer (31) is being fixed to the partition plate (24). Thereby, it is possible to prevent the elongated plate-like drain pan cover (30) from being bent and deformed by the air flow generated by the fan (25). In addition, a portion of the space between the drain pan cover (30) and the partition plate (24) where the spacer (31) is not provided is a water guide gap (G), so that the drain pan cover (30) is deformed flexibly. At the same time as deterrence, smooth drain water can be discharged.

  In the above embodiment, since the fan partition plate (32) is provided between the suction port (26a) of the fan (25) and the partition plate (24), the drain that has flowed over the partition plate (24). Water can be prevented from being sucked into the suction port (26a) of the fan (25). In addition, since the width (W) of each partition plate (24) is shorter than the diameter (D) of the suction port (26a), drain water accumulates on the partition plate (24) and the suction port (26a) of the fan (25) ) Can be deterred.

  Moreover, in the said embodiment, it inclines so that the upper surface of each fan partition plate (32) may go below as it leaves | separates from a 2nd drain pan (22). For this reason, even when drain water falls on the fan partition plate (32), the drain water flows down toward the partition plate (24) according to the inclination of the upper surface of the fan partition plate (32). Therefore, it is possible to prevent the drain water from staying on the fan partition plate (32) and being sucked into the suction port (26a) of the fan (25).

  Moreover, in the said embodiment, the 2nd drain pan (22) and the drain pan cover (30) are arrange | positioned directly under the 1st drain pan (21). Therefore, the drain water generated in the heat exchanger (20) that is not received by the first drain pan (21) is not sent on the drain pan cover (30), but is transmitted through the side plate (14) or directly to the partition plate. (24) It often falls on the top. That is, the drain water hardly falls on the drain pan cover (30), and the drain water does not easily stay on the drain pan cover (30). Therefore, it is possible to prevent the drain water from staying on the drain pan cover (30) and winding up the drain water by the fan (25).

-Modification of the embodiment-
A modification of the embodiment will be described. In this modification, the configuration of the drain pan cover (30) is different from that of the above embodiment. Hereinafter, differences from the above embodiment will be mainly described.

  The drain pan cover (30) of the present modification does not cover the entire opening of the second drain pan (22). Specifically, as shown in FIG. 8, the length in the width direction of the drain pan cover (30) is slightly shorter than the length in the width direction of the opening of the second drain pan (22). Thus, a water guide gap (G) through which drain water can pass is formed between the partition plate (24) and the drain pan cover (30).

  The drain pan cover (30) is provided on the partition plate (24) via a plurality of legs (not shown) provided on the drain pan cover (30) so as to protrude outward in the width direction. It is screwed. These leg portions are preferably provided at both ends and an intermediate portion of the drain pan cover (30) in the longitudinal direction.

  Also by this modification, the same effect as the above embodiment can be obtained.

<< Other Embodiments >>
In the said embodiment, although the spacer (31) is provided in the drain pan cover (30), the spacer (31) may be provided in the partition plate (24). In this case, the spacer (31) may be formed integrally with the partition plate (24), or may be formed separately from the partition plate (24).

  Moreover, in the said embodiment, although the partition plate (24) comprises the drain water guide member, the structure of a drain water guide member is not restricted to this. For example, a block-shaped member having an upper surface inclined so as to become lower toward the drain pan (22) may constitute the drain water guide member.

  Moreover, in the said embodiment, although the upper surface (24a) of a partition plate (24) inclines so that the whole may become low as it goes to the drain pan (22), only a part of upper surface (24a) is drain pan (22 ) May be inclined so as to become lower. In this case, it is preferable that the remaining part of the upper surface (24a) (that is, a part not inclined so as to become lower toward the drain pan (22)) is substantially horizontal.

  In the above embodiment, the air suction port (12a) is provided in the top plate (12) of the casing (11), and the air outlet (13a) is provided in the bottom plate (13) of the casing. The mouth (12a) may be provided on the bottom plate (13) of the casing (11), and the air outlet (13a) may be provided on the top plate (12) of the casing. Moreover, the air suction inlet (12a) and the air blower outlet (13a) may each be provided in the side plate (14).

  Moreover, in the said embodiment, although the spacer (31) is provided in the both ends and center part of the longitudinal direction of the drain pan cover (30), the spacer (31) is only the both ends of the longitudinal direction of the drain pan cover (30). May be provided.

  Further, the number of spacers (31) is not limited to that of the above embodiment. For example, two or more spacers (31) may be provided in the middle portion of the drain pan cover (30) in the longitudinal direction.

  Moreover, in the said embodiment, although the intermediate part of the width direction of the drain pan cover (30) is formed in the substantially horizontal flat plate shape, it is a side surface so that the said intermediate part may become low as it goes to a through-hole (30b). It may be formed in a V shape when viewed. Thereby, the drain water which exists on a drain pan cover (30) can be made to flow into a 2nd drain pan (22) more smoothly.

  The type of the fan (25) is not limited to the sirocco fan, and other types of fans such as a turbo fan and a cross flow fan can be arbitrarily applied.

  Further, the width (W) of the fan partition plate (32) may be longer than the diameter (D) of the suction port (26a) of the fan (25). Moreover, the fan partition plate (32) may not be provided.

  As described above, the present invention is useful for an indoor unit of an air conditioner.

1 Air conditioner
10 Indoor unit
11 Casing
20 heat exchanger
22 Second drain pan (drain pan)
22a Open edge
24 Partition plate (drain water guide member)
24a Top view
24b edge
25 fans
26 Fan case
26a Suction port
27 impeller
30 Drain pan cover
30a edge
31 Spacer
32 Fan divider

Claims (7)

A casing (11) through which air flows,
A heat exchanger (20) provided in the casing (11) for exchanging heat between air and a fluid flowing in the interior;
A drain pan (22) provided below the heat exchanger (20) in the casing (11) and opening upward and receiving drain water generated in the heat exchanger (20);
A drain water guide member (24) having an upper surface (24a) extending obliquely upward from the opening edge (22a) of the drain pan (22) outward;
A fan (25) provided between the heat exchanger (20) and the drain pan (22);
A drain pan cover (30) covering the opening of the drain pan (22),
An indoor unit of an air conditioner, wherein a water guide gap (G) through which drain water can pass is formed between the drain water guide member (24) and the drain pan cover (30). . In claim 1,
The edge (30a) of the drain pan cover (30) covers the edge (24b) of the drain water guide member (24) on the drain pan (22) side,
The indoor unit of an air conditioner, wherein the water guide gap (G) is formed between an edge (30a) of the drain pan cover (30) and the drain water guide member (24). In claim 2,
Provided between the drain water guide member (24) and the drain pan cover (30) to form the water guide gap (G) between the drain water guide member (24) and the drain pan cover (30). The indoor unit of the air conditioner characterized by including a spacer (31) that performs the above operation. In claim 3,
The indoor unit of the air conditioner, wherein the spacer (31) is provided on the drain pan cover (30). In claim 4,
The drain pan (22) and the drain pan cover (30) have an elongated shape extending in a predetermined direction,
The spacer (31) is provided at both ends and an intermediate portion in the longitudinal direction of the drain pan cover (30), and is fixed to the drain water guide member (24). Indoor unit. In any one of Claims 1-5,
The fan (25) has a fan case (26) in which a suction port (26a) is formed on a side surface, and an impeller (27) accommodated in the fan case (26),
The indoor unit (10) of the air conditioner is disposed below the suction port (26a) of the fan (25) and above the drain water guide member (24), and the drain water guide member ( An air conditioner indoor unit, comprising a fan partition plate (32) that covers a portion of the fan (25) located on the side of the suction port (26a) of 24). In claim 6,
The inlet (26a) of the fan (25) is formed in a circular shape,
The length (W) of the fan partition plate (32) along the side surface of the fan (25) is shorter than the diameter (D) of the suction port (26a). unit.

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