JP2007333282A - Indoor unit for air conditioner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an indoor unit 10 for air conditioner set under the roof, adaptable to a set state in which the air taken in from under the roof is fed to an indoor heat exchanger 38, and to a set state in which air taken from the interior is fed to the indoor heat exchanger 38. <P>SOLUTION: The indoor unit 10 can be constituted either in a first set state, in which air taken from under the roof is fed to the indoor heat exchanger 38 or in a second set state, in which the air taken in from the interior is fed to the indoor heat exchanger 38. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an indoor unit of an air conditioner installed behind a ceiling of an indoor space.

  Conventionally, an indoor unit of an air conditioner installed in the ceiling of an indoor space is known. Patent Document 1 discloses this type of indoor unit.

Specifically, the indoor unit of Patent Document 1 includes a support frame that is fixed to a ceiling surface of a building frame, and a casing that is attached to the lower side of the support frame. Components such as a heat exchanger, a fan, and a fan motor are attached to the support frame. The casing forms a space for accommodating the component devices attached to the support frame. Ducts communicating with the indoor space are respectively connected to the air outlet on the front surface and the air inlet on the back surface of the casing. The indoor unit is configured such that air sucked from the room passes through the heat exchanger and is supplied to the room.
Japanese Patent Laid-Open No. 11-132492

  By the way, conventionally, an indoor unit of a type that sucks air to be sent to an indoor heat exchanger from a space behind the ceiling is known. For example, in system ceilings often used in office buildings, the space behind the ceiling is not so sealed, so the air environment is rarely hot and humid compared to the indoor space, and the indoor space Become close. In such a case, since the air in the space behind the ceiling is in a state suitable as the intake air for the indoor unit, an indoor unit of a type that sucks air sent to the indoor heat exchanger from the space behind the ceiling may be used. is there.

  However, conventionally, when installing an indoor unit that sucks in air sent to the indoor heat exchanger from the space behind the ceiling, for example, if it is found that the air in the space behind the ceiling is not suitable for the air sucked into the indoor unit For example, it cannot be changed so as to suck air from the indoor space. Similarly, an indoor unit of a type that sucks air to be sent to the indoor heat exchanger from the indoor space cannot be changed to suck air from the space behind the ceiling.

  The present invention has been made in view of the above point, and the object of the present invention is to send air sucked from the ceiling back to the indoor heat exchanger for the indoor unit of the air conditioner installed on the ceiling back. It is an object of the present invention to provide an indoor unit that can handle both the installed state and the installed state in which air sucked from the room is sent to the indoor heat exchanger.

  The first invention includes a casing (34) that houses an indoor heat exchanger (38) and an indoor fan (39) and is installed behind the ceiling, and air that has passed through the indoor heat exchanger (38). The indoor unit (10) of the air conditioner supplied to the room through a duct (11) connected to the casing (34) is an object. The indoor unit (10) includes a first installation state in which the air sucked from the back of the ceiling is sent to the indoor heat exchanger (38), and the air sucked from the room is the indoor heat exchanger (38 ) To be installed in any of the second installation states sent to.

  In the first invention, the indoor unit (10) is installed so that air sucked from the back of the ceiling is sent to the indoor heat exchanger (38) in the first installed state, and from the indoor space in the second installed state. It is installed so that the sucked air is sent to the indoor heat exchanger (38). The indoor unit (10) is configured to be installable in either the first installation state or the second installation state.

  According to a second invention, in the first invention, the casing (34) has a ceiling-side inlet (23a) that can be opened in a space behind the ceiling, and an indoor-side inlet that can be opened in an indoor space. (23b) is formed and is attached to the casing (34) so as to block the indoor inlet (23b) in the first installation state, and the ceiling inlet (in the second installation state) It has a closing plate (19) attached to the casing (34) so as to close 23a).

  In the second invention, the casing (34) is formed with a ceiling-side inlet (23a) and an indoor-side inlet (23b). The indoor unit (10) includes a closing plate (19) that closes the suction port (23a) on the ceiling side or the suction port (23b) on the indoor side. In the second aspect of the invention, depending on the installation state, one suction port (23a, 23b) is closed with a closing plate (19), and the other suction port (23a, 23b) is opened to the space behind the ceiling or the indoor space. Thus, it can be installed in either the first installation state or the second installation state.

  According to a third aspect, in the second aspect, the ceiling-side suction port (23a) is formed on an upper surface of the casing (34), and the indoor-side suction port (23b) is formed on the casing (34). It is formed on the lower surface.

  In the third invention, the suction port (23a) on the ceiling side is formed on the upper surface of the casing (34), and the suction port (23b) on the indoor side is formed on the lower surface of the casing (34). Accordingly, since the upper surface and the lower surface of the casing (34) face each other, the ceiling-side suction port (23a) and the indoor-side suction port (23b) face each other.

  According to a fourth invention, in the third invention, the indoor fan (39) is configured as a multi-blade fan that sucks from the side of the fan housing (35) and blows forward, and the fan housing (35) side. It is installed such that the side faces the side surface of the casing (34) and the front side faces the indoor heat exchanger (38).

  In the fourth invention, the side of the fan housing (35) that sucks air faces the side surface of the casing (34). That is, the side of the fan housing (35) that sucks in air is in a state in which it is substantially in the same direction with respect to the upper surface of the casing (34) and the lower surface of the casing (34). Accordingly, the side of the fan housing (35) that sucks air faces substantially the same direction with respect to the ceiling-side suction port (23a) and the indoor-side suction port (23b).

  According to a fifth aspect of the present invention, in the first aspect of the present invention, the air suction port (23) is opened in only one of the constituent surfaces of the casing (34). The casing (34) is installed in a state in which the suction port (23) opens into the indoor space and the constituent surface where the suction port (23) opens is a bottom surface. In the second installation state, the suction port ( The casing (34) is installed in a state in which the constituent surface other than the constituent surface to be opened in (23) is the bottom surface.

  In the fifth invention, the casing (34) is installed so that the suction port (23) opens into the space behind the ceiling in the first installation state, and the suction port (23) in the second installation state. The casing (34) is installed so that is open to the indoor space. The same suction port (23) is used in the first installation state and the second installation state.

  A sixth invention is the above-mentioned fifth invention, wherein the first drain pan (40a) located below the indoor heat exchanger (38) in the first installation state and the first installation state in the second installation state A second drain pan (40b) located below the indoor heat exchanger (38); and in the first installation state, the second drain pan (40b) is installed in a state in which drain water is sucked from the first drain pan (40a). In the installed state, a drain pump (41) installed in a state in which drain water is sucked from the second drain pan (40b) is provided.

  In the sixth invention, the drain pump (41) is installed in a state in which drain water is sucked from the first drain pan (40a) in the first installation state, and from the second drain pan (40b) in the second installation state. It is installed with drain water sucked in. That is, the drain pump (41) is shared by the first drain pan (40a) and the second drain pan (40b).

  In the present invention, the indoor unit (10) is configured to be installable in either the first installation state or the second installation state. That is, the indoor unit (10) can cope with both the first installation state and the second installation state. Therefore, it is possible to cope with both the installation state in which air sucked from the ceiling is sent to the indoor heat exchanger (38) and the installation state in which air sucked from the room is sent to the indoor heat exchanger (38). Indoor unit (10) is provided. Since this indoor unit (10) can be used for both indoor suction and ceiling suction, it is easier to use than the conventional unit.

  In the third invention, the ceiling side suction port (23a) is formed on the upper surface of the casing (34), and the indoor side suction port (23b) is formed on the lower surface of the casing (34). The suction port (23a) on the side faces the suction port (23b) on the indoor side. That is, in the indoor unit (10), the indoor heat exchanger (38) is sandwiched between the suction ports (23a, 23b) from above and below. Accordingly, in the first installation state and the second installation state, the air passage is generally vertically symmetric from each suction port (23a, 23b) to the indoor heat exchanger (38), and the pressure loss in the air passage is It becomes almost equal. Therefore, if the rotational speed of the indoor fan (39) is the same in the first installation state and the second installation state, the air volume of the air passing through the indoor heat exchanger (38) is substantially equal. This makes it easier for the indoor unit (10) to exert the same air conditioning capability.

  In the fourth aspect of the invention, the indoor fan (39) is installed so that the side of the fan housing (35) faces the side surface of the casing (34), whereby the side of the fan housing (35) that sucks in air However, both the ceiling-side suction port (23a) and the indoor-side suction port (23b) face substantially the same direction. That is, in the first installation state and the second installation state, the side of the fan housing (35) that sucks air is the same as the suction port (23a, 23b) that sucks air in each installation state. It becomes positional relationship. Therefore, in the first installation state and the second installation state, the relationship between the rotational speed and the blown air volume in the indoor fan (39) is the same, so that the indoor unit (10) has the same air conditioning capacity regardless of the installation state. It becomes easy to demonstrate. Further, it is not necessary to adjust the operation control of the indoor fan (39) according to the installation state.

  Moreover, in 5th invention, the same inlet (23) is used by the 1st installation state and the 2nd installation state by changing the space which an inlet port (23) opens with an installation state. . Therefore, in the first installation state and the second installation state, the air sucked from the suction port (23) flows through the same portion in the casing (34). Therefore, if the rotation speed of the indoor fan (39) is the same in the first installation state and the second installation state, the air volume passing through the indoor heat exchanger (38) is also substantially equal, so This makes it easier for the indoor unit (10) to exert the same air conditioning capability.

  Moreover, in 6th invention, the drain pump (41) is changed into the 1st drain pan (40a) and the 2nd drain pan by changing the drain pan (40a, 40b) which installs a drain pump (41) according to an installation state. (40b) and shared. Accordingly, since it is not necessary to prepare the drain pump (41) for each of the first drain pan (40a) and the second drain pan (40b), the structure of the indoor unit (10) can be simplified and the manufacturing cost can be reduced. Can be reduced.

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

Embodiment 1 of the Invention
A first embodiment of the present invention will be described. The indoor unit (10) of the air conditioner of Embodiment 1 is an indoor unit (10) installed behind the ceiling of the indoor space. The indoor unit (10) constitutes an air conditioner together with an outdoor unit (not shown). The indoor unit (10) is connected to the outdoor unit via a refrigerant pipe.

  As shown in FIGS. 1 and 2, the indoor unit (10) includes a box-shaped casing (34). The casing (34) is formed in a substantially rectangular parallelepiped shape. An indoor heat exchanger (38), an indoor fan (39), a drain pan (40), and a drain pump (41) are provided in the casing (34). Two indoor heat exchangers (38) and two indoor fans (39) are provided.

  Each indoor heat exchanger (38) is configured as a cross-fin type fin-and-tube heat exchanger. Each indoor heat exchanger (38) is formed in a substantially rectangular flat plate shape as a whole. Each indoor heat exchanger (38) is erected so that the short side direction becomes the vertical direction. Each indoor heat exchanger (38) is arrange | positioned along the side surface of the longitudinal side of a casing (34) so that a longitudinal direction may correspond with the longitudinal direction of a casing (34). Each indoor heat exchanger (38) includes a gas side refrigerant pipe (12) and a liquid side refrigerant pipe (13) extending from connection ports (14, 14) provided on the short side surface of the casing (34). ) And are connected. A refrigerant pipe from the outdoor unit is connected to these connection ports (14, 14).

  Each indoor fan (39) is configured as a multi-blade fan that sucks from the side of the fan housing (35) and blows forward. Each indoor fan (39) is a so-called sirocco fan. Each indoor fan (39) includes a fan housing (35) and an impeller (36), and shares one fan motor (37).

  Each fan housing (35) is formed in the substantially cylindrical shape which has the protrusion part extended in a tangential direction. Each fan housing (35) has an air outlet formed at the tip of the protruding portion, and a suction port formed on one bottom surface of the cylindrical portion. Each fan housing (35) is arranged in a state of being arranged in the longitudinal direction of the casing (34) between two fan top plates (28) provided upright along the longitudinal direction of the casing (34). . Each fan housing (35) has an air outlet facing the indoor heat exchanger (38) and an air inlet facing the short side of the casing (34). In these fan housings (35), the protruding portions pass through different fan top plates (28), and the air outlets face different indoor heat exchangers (38).

  The fan motor (37) is disposed between the fan housings (35), and is attached to one fan top plate (28) via a fixture. The fan motor (37) is arranged such that the rotation axis is along the longitudinal direction of the casing (34). Each impeller (36) is formed in a substantially cylindrical shape, and a side surface portion includes a plurality of blades. In the side surface portion of each impeller (36), there is a gap between the blades. Each impeller (36) is housed in a fan housing (35). Each impeller (36) is connected to a rotating shaft of a fan motor (37).

  The drain pan (40) includes a drain receiving part (42) and a pump installation part (43). The drain receiving part (42) is provided below each indoor heat exchanger (38) so as to receive drain water generated by condensation of moisture in the air in each indoor heat exchanger (38). ing. Each drain receiving part (42) is formed in a substantially rectangular shape, and each extends along the indoor heat exchanger (38). The pump installation part (43) is formed in a substantially rectangular shape. One end of a drain receiving part (42) is connected to both ends of the pump installation part (43). A drain pump (41) is installed at a position near the side surface on the short side of the casing (34) in the center of the pump installation section (43). The drain pump (41) is attached to a mounting plate (27) fixed to the drain pan (40) with screws or the like. A drain pipe extending from a connection port (15) provided on a short side surface of the casing (34) is connected to the drain pump (41). A drain pipe extending outside the room is connected to the connection port (15).

  The bottom surface of each drain receiving part (42) is inclined so that the pump installation part (43) side is lowered. The pump installation part (43) is inclined from both ends toward the center so that the installation position of the drain pump (41) is lowered. As a result, the drain water dropped on the drain receiving part (42) flows into the pump installation part (43) and is collected around the drain pump (41). The drain water collected around the drain pump is discharged out of the room via the drain pipe by the drain pump (41).

  A blower outlet (22) for connecting the blowout duct (11) is formed on each of the longitudinal side surfaces of the casing (34). A suction port (23a) on the ceiling side is formed on the upper surface of the casing (34). Each of the ceiling-side suction ports (23a) opens in a state of straddling the upper side of the two indoor fans (39) on the inner side of the indoor heat exchanger (38). A suction port (23b) on the indoor side is formed on the lower surface of the casing (34). Each indoor-side suction port (23b) is open inside the indoor heat exchanger (38) so as to straddle the lower sides of the two indoor fans (39). Filters for removing dust from the intake air are respectively provided inside the inlet (23a) on the ceiling side and the inlet (23b) on the indoor side (not shown).

  The indoor unit (10) includes a closing plate (19) attached to the casing (34). The closing plate (19) is formed in a flat plate shape that is slightly larger than the suction port (23a, 23b). The closing plate (19) can be attached to the casing (34) at either a position for closing the suction port (23a) on the ceiling side or a position for closing the suction port (23b) on the indoor side.

  With the above configuration, the indoor unit (10) of the first embodiment has the first installation state in which the air sucked from the back of the ceiling is sent to the indoor heat exchanger (38), and the air sucked from the room is the indoor heat. It can be installed in any of the second installation states sent to the exchanger (38).

  In the first installation state, as shown in FIG. 2A, a closing plate (19) for closing the indoor suction port (23b) is attached to the lower surface of the casing (34). The casing (34) is hung from the housing of the building, and is installed in a state where the outer surface of the closing plate (19) is in contact with the back surface of the ceiling plate. The blowout duct (11) is connected to the blowout port (22) on the side surface of each longitudinal side of the casing (34).

  Thereby, the air in the space behind the ceiling is sucked in from the ceiling side suction port (23a) by the indoor fan (39), passes through the filter, and is sent to the indoor heat exchanger (38). The temperature of the air sent to the indoor heat exchanger (38) is adjusted when passing through the indoor heat exchanger (38). The temperature-adjusted air flows into the blowout duct (11) from the blowout port (22) and is supplied to the room.

  In the second installation state, as shown in FIG. 2 (B), the casing (34) is fitted into an opening formed in the ceiling plate with its lower surface being substantially flush with the lower surface of the ceiling plate. The casing (34) is suspended from the housing of the building. A decorative panel (21) in which a suction grill is formed corresponding to the position of the suction port (23b) on the indoor side is attached to the lower surface of the casing (34). A closing plate (19) is attached to the upper surface of the casing (34) so as to close the suction port (23a) on the ceiling side. The blowout duct (11) is connected to the blowout port (22) on the side surface of each longitudinal side of the casing (34).

  Thereby, the air in the indoor space is sucked from the indoor inlet (23b) by the indoor fan (39), passes through the filter, and is sent to the indoor heat exchanger (38). The temperature of the air sent to the indoor heat exchanger (38) is adjusted when passing through the indoor heat exchanger (38). The temperature-adjusted air flows into the blowout duct (11) from the blowout port (22) and is supplied to the room.

-Effect of Embodiment 1-
In the first embodiment, the indoor unit (10) is configured to be installable in either the first installation state or the second installation state. That is, the indoor unit (10) can cope with both the first installation state and the second installation state. Therefore, it is possible to cope with both the installation state in which air sucked from the ceiling is sent to the indoor heat exchanger (38) and the installation state in which air sucked from the room is sent to the indoor heat exchanger (38). Indoor unit (10) is provided. Since this indoor unit (10) can be used for both indoor suction and ceiling suction, it is easier to use than the conventional unit.

  In the first embodiment, the ceiling side suction port (23a) is formed on the upper surface of the casing (34), and the indoor side suction port (23b) is formed on the lower surface of the casing (34). The suction port (23a) on the side faces the suction port (23b) on the indoor side. That is, in the indoor unit (10), the indoor heat exchanger (38) is sandwiched between the suction ports (23a, 23b) from above and below. Accordingly, in the first installation state and the second installation state, the air passage is generally vertically symmetric from each suction port (23a, 23b) to the indoor heat exchanger (38), and the pressure loss in the air passage is It becomes almost equal. Therefore, if the rotational speed of the indoor fan (39) is the same in the first installation state and the second installation state, the air volume of the air passing through the indoor heat exchanger (38) is substantially equal. This makes it easier for the indoor unit (10) to exert the same air conditioning capability.

  In Embodiment 1, the indoor fan (39) is installed so that the side of the fan housing (35) faces the side surface of the casing (34), so that the air in the fan housing (35) is sucked into the side. However, both the ceiling-side suction port (23a) and the indoor-side suction port (23b) face substantially the same direction. That is, in the first installation state and the second installation state, the side of the fan housing (35) that sucks air is the same as the suction port (23a, 23b) that sucks air in each installation state. It becomes positional relationship. Therefore, in the first installation state and the second installation state, the relationship between the rotational speed and the blown air volume in the indoor fan (39) is the same, so that the indoor unit (10) has the same air conditioning capacity regardless of the installation state. It becomes easy to demonstrate. Further, it is not necessary to adjust the operation control of the indoor fan (39) according to the installation state.

-Modification of Embodiment 1-
A modification of the first embodiment will be described. In this modified example, the suction port (23a) on the ceiling side is formed on each of the side surfaces on the short side of the casing (34). The suction port (23a) on the ceiling side is formed at a position facing the air outlet of the fan housing (35) on the side surface on each short side. In this case, the connection ports (14, 15) are provided around the suction port (23a) on the ceiling side on the side surface on the short side or on the side surface on the long side.

  The suction port (23a) on the ceiling side can be formed not on the side surface on the short side of the casing (34) but on the side surface on the long side of the casing (34).

<< Embodiment 2 of the Invention >>
A second embodiment of the present invention will be described. The indoor unit (10) of the second embodiment is configured to be able to cope with the first installation state and the second installation state by turning upside down.

  As shown in FIG. 3, in the second embodiment, the casing (34) is formed in a rectangular parallelepiped shape as in the first embodiment. The casing (34) includes a flat plate (34a, 34b) serving as a top plate or a bottom plate, a long side plate (34c, 34d) extending vertically from a long side of the flat plate (34a, 34b), and a flat plate (34a, Two short side plates extending vertically from the short side of 34b) are provided. A suction port (23) is formed in one first flat plate (34a) of the two flat plates (34a, 34b). The first flat plate (34a) is a top plate in the first installation state, and a bottom plate in the second installation state. Each long side plate (34c, 34d) is formed with an air outlet (22). Although not shown, one short side plate is provided with connection ports (14, 14) for refrigerant piping and connection ports (15) for drain piping. In the second embodiment, the indoor unit (10) does not include the closing plate (19).

  The indoor unit (10) includes a first drain pan (40a), a second drain pan (40b), and a drain pump (41). The first drain pan (40a) is provided on the second flat plate (34b) side facing the first flat plate (34a) in the indoor heat exchanger (38). That is, the first drain pan (40a) is positioned below the indoor heat exchanger (38) in the first installed state. The second drain pan (40b) is provided on the first flat plate (34a) side of the indoor heat exchanger (38). That is, the second drain pan (40b) is positioned below the indoor heat exchanger (38) in the second installation state. The first drain pan (40a) and the second drain pan (40b) face each other with the indoor heat exchanger (38) interposed therebetween.

  One drain pump (41) is provided in the casing (34). The drain pump (41) is installed in the pump installation part (43) of the first drain pan (40a) in the first installation state, and is in a state of sucking drain water from the first drain pan (40a). The drain pump (41) is installed in the pump installation part (43) of the second drain pan (40b) in the second installation state, and is in a state of sucking drain water from the second drain pan (40b). Each pump installation part (43) is comprised so that attachment or detachment with the screw etc. can be carried out to the attachment plate (27) to which the drain pump (41) was attached.

  With the above configuration, the indoor unit (10) of the second embodiment has the first installation state in which the air sucked from the back of the ceiling is sent to the indoor heat exchanger (38), and the air sucked from the room is the indoor heat. It can be installed in any of the second installation states sent to the exchanger (38).

  In the first installation state, as shown in FIG. 3 (A), the casing (34) is in a state where the suction port (23) opens into the space behind the ceiling, and the first flat plate (34a) is the upper plate. Thus, the second flat plate (34b) is installed as a bottom plate. The second flat plate (34b) contacts the back surface of the ceiling plate. The blowout duct (11) is connected to the blowout port (22) on the side surface of each longitudinal side of the casing (34). The mounting plate (27) to which the drain pump (41) is attached is attached to the pump installation part (43) of the first drain pan (40a).

  In the second installation state, as shown in FIG. 3 (B), the casing (34) is in a state where the suction port (23) opens into the indoor space, and the first flat plate (34a) serves as the bottom plate. The two flat plate (34b) is installed as an upper plate. A decorative panel (21) having a suction grille corresponding to the suction port (23) is attached to the first flat plate (34a). The blowout duct (11) is connected to the blowout port (22) on the side surface of each longitudinal side of the casing (34). The mounting plate (27) to which the drain pump (41) is attached is attached to the pump installation part (43) of the second drain pan (40b).

-Effect of Embodiment 2-
In the second embodiment, the same suction port (23) is used in the first installation state and the second installation state by changing the space in which the suction port (23) opens depending on the installation state. Therefore, in the first installation state and the second installation state, the air sucked from the suction port (23) flows through the same portion in the casing (34). Therefore, if the rotation speed of the indoor fan (39) is the same in the first installation state and the second installation state, the air volume passing through the indoor heat exchanger (38) is also substantially equal, so This makes it easier for the indoor unit (10) to exert the same air conditioning capability.

  Moreover, in the said Embodiment 2, the drain pump (41) is changed into the 1st drain pan (40a) and the 2nd drain pan by changing the drain pan (40a, 40b) which installs a drain pump (41) according to an installation state. (40b) and shared. Accordingly, since it is not necessary to prepare the drain pump (41) for each of the first drain pan (40a) and the second drain pan (40b), the structure of the indoor unit (10) can be simplified and the manufacturing cost can be reduced. Can be reduced.

-Modification of Embodiment 2-
A modification of the second embodiment will be described. In this modification, one of the side plates adjacent to the first flat plate (34a) in which the suction port (23) is formed is configured to be a bottom plate in the first installation state. That is, when the casing (34) is installed such that its side plate is the bottom plate in the first installation state, the suction port (23) is opened in the lateral direction. In this modification, the casing (34) is rotated 90 degrees instead of turning upside down, so that the first flat plate (34a) becomes the bottom plate and the side plate becomes the bottom plate. It is possible to switch between 1 installation state. Note that the side plate serving as the bottom plate in the first installation state may be the long side plate (34c, 34d) or the short side plate. When the long side plates (34c, 34d) are to be the bottom plate in the first installation state, the blowing duct (11) is formed on the short side plate or the second flat plate (34b).

<< Other Embodiments >>
In the above embodiment, the indoor fan (39) may be a fan having another configuration such as a turbo fan. In this case, you may comprise so that the inhaled air may be sent in the two indoor heat exchangers (38) which pinch | interpose the indoor fan (39) with one indoor fan (39).

  In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  As described above, the present invention is useful for an indoor unit of an air conditioner that is installed behind a ceiling of an indoor space.

It is a top view inside the casing of the indoor unit concerning Embodiment 1 of the present invention. It is sectional drawing of the indoor unit which concerns on Embodiment 1 of this invention, (A) shows a 1st installation state, (B) shows a 2nd installation state. It is sectional drawing of the indoor unit which concerns on Embodiment 2 of this invention, (A) shows a 1st installation state, (B) shows a 2nd installation state.

Explanation of symbols

10 Indoor unit
11 Suction duct (duct)
19 Closure plate
23 Suction port
23a Ceiling side inlet
23b Indoor air inlet
34 Casing
35 fan housing
38 Indoor heat exchanger
39 Indoor fan
40 Drain pan
40a First drain pan
40b Second drain pan
41 Drain pump

Claims (6)

A casing (34) that houses the indoor heat exchanger (38) and the indoor fan (39) and is installed behind the ceiling is provided, and air that has passed through the indoor heat exchanger (38) is supplied to the casing (34). It is an indoor unit of an air conditioner that supplies indoors via a connected duct (11),
A first installation state in which air sucked from the ceiling is sent to the indoor heat exchanger (38), and a second installation state in which air sucked from the room is sent to the indoor heat exchanger (38) Any one of the indoor units of the air conditioner can be installed. In claim 1,
The casing (34) is formed with a ceiling-side suction port (23a) that can be opened in a space behind the ceiling, and an indoor-side suction port (23b) that can be opened in an indoor space,
The casing (34) is attached to the casing (34) so as to block the indoor inlet (23b) in the first installation state, and the casing (23a) is closed to close the ceiling inlet (23a) in the second installation state. 34) An air conditioner indoor unit comprising a closing plate (19) attached to 34). In claim 2,
An air conditioner characterized in that the suction port (23a) on the ceiling side is formed on the upper surface of the casing (34), and the suction port (23b) on the indoor side is formed on the lower surface of the casing (34). The indoor unit of the device. In claim 3,
The indoor fan (39) is configured as a multi-blade fan that sucks from the side of the fan housing (35) and blows forward, and the side of the fan housing (35) faces the side surface of the casing (34). An indoor unit of an air conditioner, wherein the indoor unit is installed so that the front faces the indoor heat exchanger (38). In claim 1,
An air inlet (23) is opened in only one of the constituent surfaces of the casing (34),
In the first installation state, the casing (34) is opened in a state in which the suction port (23) opens into the space behind the ceiling and the configuration surface other than the configuration surface of the suction port (23) is the bottom surface. Installed,
In the second installation state, the casing (34) is installed in a state in which the suction port (23) opens into the indoor space and the constituent surface where the suction port (23) opens is the bottom surface. An indoor unit of an air conditioner. In claim 5,
A first drain pan (40a) located below the indoor heat exchanger (38) in the first installation state;
A second drain pan (40b) located below the indoor heat exchanger (38) in the second installation state;
In the first installation state, the drain water is installed from the first drain pan (40a), and in the second installation state, the drain water is installed from the second drain pan (40b). An air conditioner indoor unit comprising a drain pump (41).

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