JP7348481B2 - Ceiling-mounted indoor unit and air conditioner - Google Patents

Description

The present disclosure relates to a ceiling-embedded indoor unit and an air conditioner.

BACKGROUND ART Air conditioners equipped with ceiling-embedded indoor units are known.

In the indoor unit of Patent Document 1, a heat exchanger and a blower are housed inside a casing installed in the ceiling. An air outlet is formed on the lower surface of the casing to supply air that has passed through the heat exchanger to the indoor space.

Japanese Patent Application Publication No. 2010-164294

In a ceiling-embedded indoor unit, a panel located on the bottom surface of the casing is exposed to the indoor space. An object of the present disclosure is to reduce the area of a panel of an indoor unit.

A first aspect is a ceiling-embedded indoor unit for an air conditioner that includes a casing (40), and a blower (32) and a heat exchanger (33) arranged inside the casing (40). The casing (40) is arranged in a back space (6) of the ceiling (C), and includes a casing body (40a) whose lower side is open, and a lower open part of the casing body (40a). A panel (50) is provided and exposed to the air-conditioned space (5), and the panel (50) is formed with an air outlet (51, 52) for supplying air to the air-conditioned space (5), Suction ports (46, 47) through which air is sucked are formed in the casing body (40a), and each of the air outlet (51, 52), the blower (32), and the heat exchanger (33) At least a portion thereof overlaps each other in the vertical direction.

In the first aspect, at least a portion of each of the air outlet (51, 52), the blower (32), and the heat exchanger (33) all overlap one another. Therefore, the casing (40) can be reduced in the horizontal direction, and in turn, the panel (50) can be reduced in the horizontal direction.

In a second aspect, in the first aspect, the casing (40) has a long side extending along the ceiling (C) and a short side shorter than the long side.

In a second embodiment, a panel (50) can be formed that extends along the ceiling (C).

In a third aspect, in the second aspect, the total area of the lower surface of the panel (50) including the air outlet (51, 52) is S1, and the total opening area of the air outlet (51, 52) is S2. Then, the total opening area S2 is 20% or more of the total area S1.

In the third aspect, the opening area of the air outlet (51, 52) relative to the panel (50) is relatively large.

In a fourth aspect, in the second or third aspect, the blower (32) is a cross flow fan extending in the longitudinal direction of the casing (40).

In the fourth aspect, since the casing (40) and the blower (32) extend in the same direction, dead space within the casing (40) can be reduced.

In a fifth aspect, in any one of the first to fourth aspects, the suction port (46, 47) is formed in at least one side plate (41, 42) of the casing body (40a).

The term "side plates" as used herein refers to plates that form left and right, front and rear surfaces, and does not include plates that form upper and lower surfaces.

In the fifth aspect, the suction ports (46, 47) can be secured in the side plates (41, 42) without forming the suction ports (46, 47) on the upper plate of the casing body (40a).

In a sixth aspect, in the fifth aspect, the suction ports (46, 47) are formed in two mutually opposing side plates (41, 42) of the casing body (40a), respectively.

In the sixth aspect, suction ports (46, 47) can be secured in the side plates (41, 42) on both sides of the casing body (40a), respectively.

In a seventh aspect, in any one of the first to sixth aspects, the heat exchanger (33) is arranged near the first side plate (41) of the casing body (40a). an exchange part (33A), and a second heat exchange part (33B) arranged near a second side plate (42) opposite to the first side plate (41) of the casing main body (40a), The first heat exchange section (33A) and the second heat exchange section (33B) are arranged so as to be inclined so that the distance between them increases toward the bottom.

In the seventh aspect, the heat exchange parts (33A, 33B) can be arranged to correspond to the respective suction ports (46, 47) of the respective side plates (41, 42). By tilting the heat exchange parts (33A, 33B), the heat transfer area can be expanded.

In an eighth aspect, in any one of the first to seventh aspects, the panel (50) includes a filter (71, 72) that captures dust in the air sucked into the suction port (46, 47). A slit (54, 55) is formed in which the filter (71, 72) is drawn out of the casing (40).

In the eighth aspect, the filters (71, 72) can be inserted and removed without removing the panel (50) from the casing body (40a).

A ninth aspect is an air conditioner including an outdoor unit (20) and any one of the first to eighth ceiling-embedded indoor units (30).

FIG. 1 is a piping system diagram showing the overall configuration of an air conditioner according to an embodiment. FIG. 2 is an enlarged perspective view of a part of the internal structure of the system ceiling. FIG. 3 is a perspective view of a part of the system ceiling viewed from the indoor space side. FIG. 4 is a longitudinal sectional view of the indoor unit. FIG. 5 is a bottom view of the ceiling panel of the indoor unit. FIG. 6 is a schematic configuration diagram of the indoor unit showing the flow of air in the indoor space and the attic space. FIG. 7 is a diagram corresponding to FIG. 4, showing a state in which a part of the filter is pulled out. FIG. 8 is a diagram corresponding to FIG. 6 of an indoor unit according to modification 1. FIG. 9 is a schematic configuration diagram showing the internal structure of an indoor unit according to modification 2.

Embodiments of the present disclosure will be described below with reference to the drawings. Note that the following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its applications, or its uses.

《Embodiment》
<Overview of air conditioner>
The air conditioner (10) of the embodiment adjusts the temperature of the air in the air-conditioned space (5). The air conditioner (10) is applied to buildings, etc. The air-conditioned space (5) is an indoor space. The air conditioner (10) includes an outdoor unit (20) and at least one indoor unit (30). The air conditioner (10) of this example is configured in a so-called multi-type having a plurality of indoor units (30). The indoor unit (30) is a ceiling-embedded type. The outdoor unit (20) is installed outdoors. The indoor unit (30) and the outdoor unit (20) are connected to each other via a gas communication pipe (12) and a liquid communication pipe (13).

<Refrigerant circuit configuration>
As shown in FIG. 1, the air conditioner (10) includes a refrigerant circuit (11). The refrigerant circuit (11) is filled with refrigerant. In the refrigerant circuit (11), a refrigeration cycle is performed by circulating refrigerant. The outdoor unit (20) has an outdoor circuit (21) and an outdoor fan (22). Each indoor unit (30) has an indoor circuit (31) and an indoor fan (32). The refrigerant circuit (11) includes an outdoor circuit (21), an indoor circuit (31), and communication pipes (12, 13) that connect these to each other.

The outdoor circuit (21) includes a compressor (23), an outdoor heat exchanger (24), an outdoor expansion valve (25), and a four-way switching valve (26). The compressor (23) compresses the refrigerant and discharges the compressed refrigerant. The outdoor heat exchanger (24) exchanges heat between the outdoor air conveyed by the outdoor fan (22) and the refrigerant. The outdoor heat exchanger (24) is a fin-and-tube type. The outdoor expansion valve (25) is a pressure reduction mechanism that reduces the pressure of the refrigerant. The outdoor expansion valve (25) is, for example, an electronic expansion valve.

The four-way switching valve (26) is a flow path switching mechanism for switching between the first refrigeration cycle (cooling cycle) and the second refrigeration cycle (heating cycle). The four-way switching valve (26) switches between a first state (the state shown by the solid line in FIG. 1) and a second state (the state shown by the broken line in FIG. 1).

Each indoor circuit (31) has an indoor heat exchanger (33) and an indoor expansion valve (34). The indoor heat exchanger (33) exchanges heat between the indoor air conveyed by the indoor fan and the refrigerant. The indoor heat exchanger (33) is a fin-and-tube type. The indoor expansion valve (34) is a pressure reduction mechanism that reduces the pressure of the refrigerant. The indoor expansion valve (34) is, for example, an electronic expansion valve.

In the cooling operation, the four-way switching valve (26) is in the first state and the first refrigeration cycle is performed. In the first refrigeration cycle, the refrigerant compressed by the compressor (23) releases heat in the outdoor heat exchanger (24), is depressurized in the indoor expansion valve (34), and evaporates in the indoor heat exchanger (33).

In the second refrigeration cycle, the four-way switching valve (26) is in the second state, and the second refrigeration cycle is performed. The refrigerant compressed by the compressor (23) releases heat in the indoor heat exchanger (33), is depressurized in the outdoor expansion valve (25), and evaporates in the outdoor heat exchanger (24).

<System ceiling>
As shown in FIGS. 2 and 3, the indoor unit (30) is applied to the system ceiling (C). The system ceiling (C) is a so-called line type. As shown in FIG. 2, the system ceiling (C) has a plurality of bars (B1, B2) arranged in a grid pattern and a ceiling wall (W) fitted between each bar (B1, B2). .

The plurality of bars (B1, B2) include a plurality of first bars (B1) and a plurality of second bars (B2). The first bar (B1) extends in the front-rear direction. The plurality of first bars (B1) are arranged in the left-right direction in parallel to each other. The second bar (B2) extends in the left-right direction. The plurality of second bars (B2) are arranged in the front-rear direction in parallel to each other. The first bar (B1) and the second bar (B2) are orthogonal to each other. A lattice structure is formed by the plurality of first bars (B1) and the plurality of second bars (B2). The first bar (B1) has an inverted T-shaped longitudinal section. In other words, the lower end of the first bar (B1) is formed with convex portions (7) that protrude from both sides in the width direction.

The system ceiling (C) has hanging bolts and fixing fittings (not shown). Hanging bolts are secured to the upper slab of the system ceiling. The first bar (B1) and the second bar (B2) are supported by the lower ends of the hanging bolts via fixing fittings.

A first opening (O1) and a second opening (O2) are formed between the plurality of first bars (B1) and the plurality of second bars (B2). The left and right widths of the first opening (O1) are smaller than the left and right widths of the second opening. The plurality of first bars (B1) include a plurality of pairs of first bars (B1) (line bars (LB)) having relatively narrow intervals between them. A first opening (O1) is formed between the pair of first bars (B1).

In principle, a ceiling wall (W) is fitted into each second opening (O2). Similarly, in principle, a ceiling wall (W) is fitted into each first opening (O1). The ceiling wall (W) is installed on the upper surface of each convex portion (7) of the first bar (B1) and the second bar (B2). An attic space (6) is formed behind (above) the ceiling wall (W) of the system ceiling (C). An indoor space (5) is formed on the front side (lower side) of the ceiling wall (W) of the system ceiling.

A lighting device (8) is fitted into some of the first openings (O1) (see FIG. 3). The lighting device (8) is installed on the upper surface of each convex portion (7) of the first bar (B1) and the second bar (B2). The lighting device (8) is formed into a substantially rectangular shape extending along the pair of line bars (LB).

The casing (40) (strictly speaking, the casing body (40a)) of the indoor unit (30) is fitted into some of the first openings (O1) of the plurality of first openings (O1). The casing body (40a) is installed on the upper surface of each convex portion (7) of the first bar (B1) and the second bar (B2). The casing body (40a) extends along a pair of line bars (LB).

In the line type system ceiling (C), the lighting device (8) and the indoor unit (30) are arranged linearly in the longitudinal direction thereof. This gives the ceiling a clean appearance.

<Overview of indoor unit>
The indoor unit (30) will be explained with reference to FIGS. 2 to 5. The indoor unit (30) is installed in the first opening (O1) of the system ceiling (C). The indoor unit (30) includes a casing (40), an indoor fan (32), an indoor heat exchanger (33), a drain pan (35, 36), a flow path forming member (60), and a filter (71, 72).

<casing>
As shown in FIG. 4, the casing (40) includes a casing body (40a) whose lower side is open, and a ceiling panel (50) provided at the lower open part of the casing body (40a). An air passage (P) through which air flows is formed inside the casing (40). The casing (40) is formed to be horizontally long and extends along the system ceiling (C).

<Casing body>
The casing body (40a) is placed in the attic space (6). The ceiling panel (50) is exposed to the indoor space (5) so as to form a ceiling surface.

The casing body (40a) is formed into a hollow box shape having long sides extending along the ceiling and short sides shorter than the long sides. Specifically, the casing body (40a) is formed into an elongated rectangular parallelepiped shape extending in the longitudinal direction of the first bar (B1).

The casing body (40a) has four side plates (41, 42, 43, 44) and one top plate (45). The upper plate (45) is located above the casing (40).

The four side plates include a first side plate (41), a second side plate (42), a third side plate (43), and a fourth side plate (44). The first side plate (41) is located on the left side of the casing (40). The second side plate (42) is located on the right side of the casing (40). The third side plate (43) is located on the front side of the casing (40). The fourth side plate (44) is located on the rear side of the casing (40). The first side plate (41) and the second side plate (42) are side plates along the long sides of the casing (40). The first side plate (41) and the second side plate (42) face each other. The first side plate (41) and the second side plate (42) extend in the longitudinal direction of the first bar (B1) along the first bar (B1). The third side plate (43) and the fourth side plate (44) are side plates along the short side of the casing (40). The third side plate (43) and the fourth side plate (44) extend in the longitudinal direction of the second bar (B2) along the second bar (B2).

As shown in FIGS. 4 and 5, a first suction port (46) and a second suction port (47) are formed in the casing body (40a). Indoor air from the indoor space (5) is sucked into the first suction port (46) and the second suction port (47) through the ventilation port (9) and the attic space (6), which will be described in detail later.

The first suction port (46) is formed in the first side plate (41). The first suction port (46) is formed in a rectangular shape along the outer edge of the first side plate (41). The first suction port (46) extends from near the top end to near the bottom end of the first side plate (41). The first suction port (46) extends in the longitudinal direction of the casing (40) from near the front end to near the rear end of the first side plate (41).

The second suction port (47) is formed in the second side plate (42). The second suction port (47) is formed in a rectangular shape along the outer edge of the second side plate (42). The second suction port (47) extends from near the top end to near the bottom end of the second side plate (42). The second suction port (47) extends in the longitudinal direction of the casing (40) from near the front end to near the rear end of the second side plate (42).

<Ceiling panel>
As shown in FIGS. 4 and 5, the ceiling panel (50) constitutes the lower surface of the casing (40). The ceiling panel (50) is exposed to the interior space (5). The ceiling panel (50) is formed into an elongated rectangular shape. The ceiling panel (50) extends in the direction along the line bar (LB).

A first air outlet (51) and a second air outlet (52) are formed in the ceiling panel (50). The first air outlet (51) and the second air outlet (52) supply air inside the casing (40) into the room. The first air outlet (51) and the second air outlet (52) extend in the longitudinal direction of the ceiling panel (50). The first air outlet (51) and the second air outlet (52) are arranged parallel to each other and adjacent to each other.

A wind direction adjusting plate (53) is provided at each of the first air outlet (51) and the second air outlet (52). The wind direction adjusting plate (53) extends along each outlet (51, 52) in the longitudinal direction of the outlet (51, 52). The angle of each wind direction adjusting plate (53) is adjusted by a motor (not shown). The angle of the wind direction adjustment plate (53) is adjusted between a position where the air outlet (51, 52) is closed and a position where the air outlet (51, 52) is opened. The wind direction adjustment plate (53) adjusts the direction of airflow blown out from the air outlet (51, 52).

A first slit (54) and a second slit (55) are formed in the ceiling panel (50). The first slit (54) is formed between the left edge of the ceiling panel (50) and the first slit (54). The second slit (55) is formed between the right edge of the ceiling panel (50) and the second slit (55). The first slit (54) and the second slit (55) extend in the longitudinal direction of the ceiling panel (50). The pull-out portions (71b, 72b) of the corresponding filters (71, 72) fit into the first slit (54) and the second slit (55).

<Indoor fan>
The indoor fan (32) is a blower that conveys air. The indoor fan (32) in this example is composed of a cross-flow fan (also referred to as a cross-flow fan). The indoor fan (32) is arranged in the middle part of the casing (40) in the width direction (left and right direction). The indoor fan (32) is arranged in the middle part of the casing (40) in the height direction.

The indoor fan (32) extends in the longitudinal direction of the casing (40). In other words, the rotating shaft of the indoor fan (32) extends in the longitudinal direction of the casing (40) or the line bar (LB). Since the cross flow fan (32) has an elongated shape, the dead volume will be reduced even if the casing (40) is made elongated.

<Outdoor heat exchanger>
The outdoor heat exchanger (24) is arranged inside the casing (40). The outdoor heat exchanger (24) has a first heat exchange section (33A) and a second heat exchange section (33B). The first heat exchange section (33A) is arranged closer to the first side plate (41). The first heat exchange section (33A) is arranged at a position corresponding to the first suction port (46). The second heat exchange section (33B) is arranged closer to the second side plate (42). The second heat exchange part (33B) is arranged at a position corresponding to the second suction port (47).

The first heat exchange section (33A) and the second heat exchange section (33B) include a large number of fins (F) and heat transfer tubes (not shown) that penetrate each fin (F). A large number of fins (F) are arranged in the longitudinal direction of the casing (40) or the indoor fan (32).

The first heat exchange section (33A) and the second heat exchange section (33B) are slightly inclined from the vertical direction. Specifically, the first heat exchange section (33A) is obliquely inclined so that its upper portion is closer to the middle section in the width direction of the casing (40). The second heat exchange part (33B) is inclined obliquely so that its upper part approaches the middle part in the width direction of the casing (40). In other words, the first heat exchange section (33A) and the second heat exchange section (33B) are arranged so as to be inclined so that the distance from each other increases toward the bottom. As a result, a space with a relatively wide interval in the width direction is formed between the lower part of the first heat exchange part (33A) and the lower part of the second heat exchange part (33B). An indoor fan (32) is placed in this space.

<Drain pan>
A first drain pan (35) and a second drain pan (36) are arranged inside the casing (40). The first drain pan (35) is arranged below the first heat exchange section (33A). The first drain pan (35) is a tray that receives condensed water generated around the first heat exchange section (33A). The second drain pan (36) is a tray that receives condensed water generated around the second heat exchange section (33B). The first drain pan (35) extends in the longitudinal direction of the casing (40) along the first side plate (41). The second drain pan (36) extends in the longitudinal direction of the casing (40) along the second side plate (42).

<Flow path forming member>
The flow path forming member (60) is arranged below the indoor fan (32). The channel forming member (60) forms a main channel (61) that covers the lower part of the indoor fan (32), and two branch channels (62, 63) that branch left and right from the lower part of the main channel (61). are doing. The flow path forming member (60) extends in the longitudinal direction of the casing (40). The two branch channels (62, 63) include a first branch channel (62) connected to the first outlet (51) and a second branch channel (63) connected to the second outlet (52). .

<filter>
A first filter (71) and a second filter (72) are arranged inside the casing (40). Each filter (71, 72) is formed in a plate or sheet shape. The first filter (71) and the second filter (72) are arranged upstream of the indoor heat exchanger (33) in the air passageway (P). The first filter (71) and the second filter (72) collect dust in the air.

The first filter (71) is arranged on the back side of the first suction port (46) so as to cover the first suction port (46). The first filter (71) extends vertically from the upper plate (45) to the ceiling panel (50). The first filter (71) is attached to the casing (40) in a vertically erected manner. The first filter (71) has a first filter body (71a) that covers the first suction port (46), and a first drawer part (71b) connected to the lower end of the first filter body (71a). When the first filter (71) is attached, the first drawer portion (71b) projects downward from the first slit (54). The first drawer part (71b) is provided with a handle (73) for an operator or user to pull out the first filter (71).

Similarly, the second filter (72) is arranged on the back side of the second suction port (47) so as to cover the second suction port (47). The second filter (72) extends vertically from the top plate (45) to the ceiling panel (50). The second filter (72) is attached to the casing (40) in a vertically erected manner. The second filter (72) has a second filter body (72a) that covers the second suction port (47), and a second drawer part (72b) connected to the lower end of the second filter body (72a). When the second filter (72) is attached, the second drawer portion (72b) projects downward from the second slit (55). The second drawer part (72b) is provided with a handle (73) for an operator or user to pull out the second filter (72).

<vent>
As schematically shown in FIG. 6, the system ceiling (C) is provided with a vent (9) that communicates the indoor space (5) with the attic space (6). The suction ports (46, 47) of the indoor unit (30) communicate with the indoor space (5) via the vent (9) and the attic space (6). The suction ports (46, 47) are configured to substantially suck indoor air from the indoor space (5).

-Driving behavior-
The operation of the air conditioner (10) will be explained. The air conditioner (10) switches between cooling operation and heating operation. Below, cooling operation will be explained as a representative example.

In the cooling operation, the outdoor fan (22), the indoor fan (32), and the compressor (23) are operated. As a result, the first refrigeration cycle described above is performed. When the indoor fan (32) is in operation, indoor air in the indoor space (5) is sucked into the attic space (6) through the vent (9). Air in the attic space (6) is sucked into the air passage (P) in the casing (40) through the first suction port (46) and the second suction port (47).

Air sucked in from the first suction port (46) passes through the first filter (71). The first filter (71) collects dust in the air. The air that has passed through the first filter (71) is cooled in the first heat exchange section (33A). Air sucked in from the second suction port (47) passes through the second filter (72). The second filter (72) collects dust in the air. The air that has passed through the second filter (72) is cooled in the second heat exchange section (33B).

Air cooled by the indoor heat exchanger (33) flows through the main passage (61) and is divided into a first branch passage (62) and a second branch passage (63). Air in the first branch flow path (62) is supplied to the indoor space (5) from the first outlet (51). Air in the second branch flow path (63) is supplied to the indoor space (5) from the second outlet (52).

In the heating operation, the second refrigeration cycle described above is performed. The heating operation is basically the same as the cooling operation except that the air is heated by the indoor heat exchanger (33).

<Layout of indoor unit parts>
As shown in FIG. 4, in the indoor unit (30), at least a portion of each of the air outlet (51, 52), the indoor fan (32), and the indoor heat exchanger (33) overlap each other in the vertical direction. There is. Specifically, in this example, the upper part of the first heat exchange section (33A), the left side portion of the indoor fan (32), and the first air outlet (51) overlap in the vertical direction. The upper part of the second heat exchange part (33B), the right side of the indoor fan (32), and the second suction port (47) overlap in the vertical direction. In this way, by arranging the indoor fan (32), the indoor heat exchanger (33), and the air outlet (51, 52) in a vertically stacked manner, the casing (40) can be reduced in the horizontal direction. Thereby, the area of the ceiling panel (50) exposed to the indoor space (5) can be reduced.

In addition, the ceiling panel (50) of this example does not have any suction ports (46, 47) formed therein. Therefore, the area of the ceiling panel (50) can be made smaller than that of the ceiling panel (50) in which the suction port is formed.

In this example, the casing (40) has a large front and rear length and a small left and right width. Therefore, as shown in FIG. 3, the indoor unit (30) can be placed between the pair of line bars (LB) together with the lighting device (8). Thereby, the indoor unit (30) and the lighting device (8) can be arranged linearly in their longitudinal direction. Therefore, a ceiling surface with a clean impression can be formed.

Assuming that the left and right length of the ceiling panel (50) is L1, and the front and back length is L2, the aspect ratio A of the ceiling panel (50) is L2/L1. The aspect ratio A is preferably 1.25 or more, more preferably 3.0 or more, and even more preferably 4.0 or more.

The total area including the air outlets (51, 52) on the lower surface of the ceiling panel (50) is S1, and the total opening area of the air outlets (51, 52) is S2. Strictly speaking, the total opening area S2 in this example is the sum of the opening area of the first air outlet (51) and the opening area of the second air outlet (52). It is preferable that the total opening area S2 is 20% or more of the total area S1. By setting the total opening area to 20% or more, a sufficient flow rate of the blown air can be ensured.

<Filter insertion/removal work>
Persons in the room, such as workers and users, remove and attach the filters (71, 72) from the indoor space (5).

In the removal work of the filters (71, 72), a person in the room grabs the handle (73) of the drawer part (71b, 72b) of the filter (71, 72) and pulls the drawer part (71b, 72b) downward. The filters (71, 72) then move downward through the slits (54, 55) (see Figure 7). Thereby, the filters (71, 72) can be taken out of the casing (40) without removing the ceiling panel (50) from the casing body (40a).

In the installation work of the filters (71, 72), a person in the room grabs the handle (73) of the drawer (71b, 72) and inserts the upper end of the filter (71, 72) into the slit (54, 55). In this state, push the filters (71, 72) upward. Thereby, the filters (71, 72) can be attached to the inside of the casing (40) without removing the ceiling panel (50) from the casing body (40a).

-Effects of embodiment-
The embodiment is a ceiling-embedded type for an air conditioner (10) that includes a casing (40), an indoor fan (32) and an indoor heat exchanger (33) arranged inside the casing (40). It is an indoor unit (30). The casing (40) is placed in the attic space (6) of the system ceiling (C) and has a casing body (40a) that is open at the bottom, and a casing body (40a) that is installed in the open bottom part of the casing body (40a) and is installed in the attic space (6) of the system ceiling (C). A panel (50) exposed to the space (5). Air outlets (51, 52) that supply air to the indoor space (5) are formed in the ceiling panel (50). Suction ports (46, 47) through which air from the indoor space (5) is sucked are formed in the casing body (40a). At least a portion of each of the air outlet (51, 52), the indoor fan (32), and the indoor heat exchanger (33) overlaps each other in the vertical direction.

In this form, since at least a portion of each of the air outlet (51, 52), the indoor fan, and the indoor heat exchanger (33) overlaps each other in the vertical direction, the casing (40) can be reduced in the horizontal direction. Thereby, the area of the ceiling panel (50) facing the indoor space (5) can also be reduced.

In this form, the suction ports (46, 47) are not formed in the ceiling panel (50), but the suction ports (46, 47) are formed in the casing body (40a). Therefore, the area of the ceiling panel (50) can be made smaller compared to a configuration in which the suction ports (46, 47) are formed in the ceiling panel (50). In addition, it is possible to avoid a so-called short circuit in which the air blown out from the air outlet (51, 52) is immediately sucked into the air inlet (46, 47).

In the embodiment, the casing (40) has a long side that extends in a direction along the system ceiling (C) and a short side that is shorter than the long side.

In this form, the casing (40) is formed into a rectangular parallelepiped shape extending along the system ceiling (C), so the casing (40) can be employed in the line-type system ceiling (C). Specifically, the indoor unit (30) is installed together with the lighting device (8) between a pair of elongated line bars (LB), and these are arranged in a straight line (see FIG. 3). This gives the ceiling a clean impression and improves the comfort of the occupants.

In the embodiment, if the total area including the air outlets (51, 52) on the lower surface of the ceiling panel (50) is S1, and the total opening area of the air outlets (51, 52) is S2, the total opening area S2 is the total area It is 20% or more of S1.

In this embodiment, a relatively large total opening area S2 of the air outlets (51, 52) can be ensured while reducing the area of the ceiling panel (50). A sufficient flow rate of the blown air can be ensured, and the pressure loss of the blown air can be reduced. Since there is no suction port in the ceiling panel (50), even if the opening area of the air outlet (51, 52) is increased in this way, a so-called short circuit will not occur.

In the embodiment, the suction ports (46, 47) are formed in at least one side plate (41, 42) of the casing body (40a).

In this form, by forming the suction ports (46, 47) on the side plates (41, 42) having a relatively large area, a sufficient area of the suction ports (46, 47) can be secured. If the suction ports (46, 47) are formed on the upper surface of the casing body (40a), there is a possibility that sufficient air cannot be sucked in due to the height restriction (slab, etc.) of the attic space (6). This embodiment is not subject to such restrictions.

In the embodiment, the suction ports (46, 47) are formed in two mutually opposing side plates (41, 42) of the casing body (40a), respectively.

In this form, the area of the suction ports (46, 47) can be further increased.

In the embodiment, the indoor heat exchanger (33) includes a first heat exchange part (33A) disposed near the first side plate (41) of the casing body (40a), and a first side plate (41) of the casing body (40a). 41), and a second heat exchange part (33B) disposed near the second side plate (42) opposite to the second heat exchange part (33B). The first heat exchange section (33A) and the second heat exchange section (33B) are arranged so as to be inclined so that the distance between them increases as they go downward.

In this form, the air sucked in from the suction ports (46, 47) of the first side plate (41) is passed through the first heat exchanger (33A), and at the same time, the air is passed through the suction ports (46, 47) of the second side plate (42). ) can be passed through the second heat exchange section (33B). Since the first heat exchange section (33A) and the second heat exchange section (33B) are inclined with respect to the vertical, the heat transfer area of each heat exchange section (33A, 33B) can be increased. In addition, the casing (40) can be made smaller in the horizontal direction compared to the case where the heat exchange parts (33A, 33B) are placed horizontally.

In an embodiment, the indoor fan (32) is a cross-flow fan that extends in the longitudinal direction of the casing (40).

By arranging the crossflow fan along the elongated casing (40), dead space can be reduced and the width of the casing (40) from side to side can be reduced. The casing (40) is horizontally elongated so that it can be adapted to line system ceilings (C).

In an embodiment, the casing (40) has a long side that extends along the system ceiling (C) and a short side that is shorter than the long side. The casing body (40a) has a first side plate (41) along the long side of the casing body (40a), and a second side plate (42) facing the first side plate (41). The suction ports (46, 47) are formed in the first side plate (41) and the second side plate (42), respectively. The indoor heat exchanger (33) includes a first heat exchange part (33A) disposed near the first side plate (41) of the casing body (40a), and a first heat exchange part (33A) disposed near the first side plate (41) of the casing body (40a). It has a second heat exchange part (33B) arranged near the opposing second side plate (42). The first heat exchange section (33A) and the second heat exchange section (33B) are arranged so as to be inclined so that the distance between them increases toward the bottom. The indoor fan (32) is a cross-flow fan that extends in the longitudinal direction of the casing (40). The cross flow fan (32) is arranged between the lower part of the first heat exchange part (33A) and the lower part of the second heat exchange part (33B).

In this form, the horizontally elongated indoor fan (32) can be placed in the space between the lower portions of the first heat exchange section (33A) and the second heat exchange section (33B). This makes it possible to reduce dead space within the casing (40). By placing the indoor fan (32) in this space, the height of the casing (40) can also be reduced.

The embodiment includes filters (71, 72) that capture dust in the air sucked into the suction ports (46, 47). A slit (54, 55) is formed in the ceiling panel (50) to draw out the filter (71, 72) to the outside of the casing (40).

In this embodiment, the filters (71, 72) can be easily inserted and removed from the indoor space (5) without removing the ceiling panel (50) from the casing body (40a).

《Modification of embodiment》
The above embodiment may be modified as follows.

<Modification 1>
The air conditioner (10) of Modification Example 1 shown in FIG. 8 includes a first duct (D1) and a second duct (D2). In this example, a first vent (9a) and a second vent (9b) are provided in the system ceiling (C). The inflow end of the first duct (D1) is connected to the first vent (9a). The outflow end of the first duct (D1) is connected to the first suction port (46). The inflow end of the second duct (D2) is connected to the second ventilation port (9b), and the outflow end of the second duct (D2) is connected to the second suction port (47). The basic configuration of the indoor unit (30) is the same as that of the above embodiment.

In Modification 1, when the indoor fan (32) is operated, indoor air in the indoor space (5) is sucked into the first duct (D1) via the first suction port (46). Air in the first duct (D1) flows into the air passage (P) of the indoor unit (30) from the first suction port (46). Air in the second duct (D2) flows into the air passage (P) of the indoor unit (30) from the second suction port (47). The air in the air passage (P) is cooled or heated by the indoor heat exchanger (33), and then supplied to the indoor space (5) from the air outlet (51, 52).

<Modification 2>
In the casing (40) of modification 2 shown in FIG. 9, an indoor fan (32), an indoor heat exchanger (33), and air outlets (51, 52) are arranged so as to overlap in the vertical direction. . The indoor fan (32) of Modification 2 is a sirocco fan. The indoor heat exchanger (33) is of a horizontal type in which the longitudinal direction of the fins is horizontal. Also in the second modification, the casing (40) can be made smaller in the horizontal direction by arranging the indoor fan (32), the indoor heat exchanger (33), and the air outlet (51, 52) one above the other in the vertical direction. As a result, the area of the ceiling panel (50) can be reduced. The indoor heat exchanger (33) may be placed diagonally.

《Other embodiments》
The above embodiment and each modification may have the following configuration.

The air conditioner (10) may be of a so-called pair type, having one outdoor unit (20) and one indoor unit (30).

The ceiling panel (50) does not necessarily have to be rectangular, and may be square, for example.

The suction ports (46, 47) may be formed in the upper plate (45) of the casing body (40a).

The indoor unit (30) may suck outdoor air into the suction ports (46, 47), adjust the temperature of the sucked air, and supply the air to the air-conditioned space (indoor space (5)). In this case, the outdoor air may be drawn directly into the suction ports (46, 47) through the duct, or the outdoor air may be drawn indirectly into the suction ports (46, 47) through the attic space (6). May be inhaled.

The indoor unit (30) does not necessarily have to be applied to the line-type ceiling panel (50).

Although the embodiments and modifications have been described above, it will be understood that various changes in form and details can be made without departing from the spirit and scope of the claims. In addition, the above embodiments, modifications, and other embodiments may be combined or replaced as appropriate, as long as the functionality of the object of the present disclosure is not impaired. The descriptions of “first,” “second,” “third,” etc. mentioned above are used to distinguish the words to which these descriptions are given, and even the number and order of the words are limited. It's not something you do.

As described above, the present disclosure is useful for indoor units and air conditioners.

5 Indoor space (air-conditioned space)
6 Attic space (back side space)
10 Air conditioner 20 Outdoor unit 30 Indoor unit 32 Indoor fan (blower, cross flow fan, sirocco fan)
33 Heat exchanger 33A First heat exchange section 33B Second heat exchange section 40 Casing 40a Casing body P6
41 First side plate 42 Second side plate 46 First suction port 47 Second suction phrase 50 Panel 51 First outlet 52 Second outlet 54 First slit 55 Second slit 71 First filter 72 Second filter

Claims (7)

A ceiling-embedded indoor unit for an air conditioner, comprising a casing (40), a blower (32) and a heat exchanger (33) arranged inside the casing (40),
The casing (40) is
A casing body (40a) that is placed in the back space (6) of the ceiling (C) and has an open bottom;
a panel (50) provided in the lower open part of the casing body (40a) and exposed to the air-conditioned space (5);
Air outlets (51, 52) are formed in the panel (50) to supply air to the air-conditioned space (5),
A suction port (46, 47) through which air is sucked is formed in the casing body (40a),
At least a portion of each of the air outlet (51, 52), the blower (32), and the heat exchanger (33) overlaps each other in the vertical direction ,
The casing body (40a) has a first side plate (41) and a second side plate (42) facing each other,
The suction ports (46, 47) include a first suction port (46) formed in the first side plate (41) and a second suction port (47) formed in the second side plate (52). including
The heat exchanger (33) is
a first heat exchange part (33A) arranged near the first side plate (41) of the casing main body (40a) and arranged at a position corresponding to the first suction port (46);
a second heat exchange part (33B) arranged near the second side plate (42) of the casing main body (40a) and arranged at a position corresponding to the second suction port (47);
At least a portion of each of the air outlet (51, 52), the blower (32), and the first heat exchange section (33A) overlaps each other in the vertical direction,
At least a portion of each of the air outlet (51, 52), the blower (32), and the second heat exchange section (33B) overlaps each other in the vertical direction.
This is a ceiling-mounted indoor unit. In claim 1,
A ceiling-embedded indoor unit, wherein the casing (40) has a long side extending along the ceiling (C) and a short side shorter than the long side. In claim 2,
Assuming that the total area including the air outlet (51, 52) on the lower surface of the panel (50) is S1, and the total opening area of the air outlet (51, 52) is S2,
A ceiling-embedded indoor unit, wherein the total opening area S2 is 20% or more of the total area S1. In claim 2 or 3,
A ceiling-embedded indoor unit characterized in that the blower (32) is a cross-flow fan extending in the longitudinal direction of the casing (40). In any one of claims 1 to 4 ,
The first heat exchange part (33A) and the second heat exchange part (33B) are each arranged at an angle so that the distance between them increases as they go downward. Indoor unit. In any one of claims 1 to 5 ,
A filter (71, 72) is provided to capture dust in the air sucked into the suction port (46, 47),
A ceiling-embedded indoor unit characterized in that the panel (50) is formed with a slit (54, 55) for drawing out the filter (71, 72) to the outside of the casing (40). outdoor unit (20),
An air conditioner comprising the ceiling-embedded indoor unit (30) according to any one of claims 1 to 6 .

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