JP2020085402A - Indoor unit for air conditioning device - Google Patents

Abstract

To control detection temperature of suction air from becoming inaccurate, in a ceiling installation type indoor unit including a ventilation port (115) for introducing outdoor air into a casing (33).SOLUTION: An indoor unit includes a ventilation port (115) and a temperature sensor (116) which are arranged on a windward side with respect to a heat exchanger (31). A shortest distance D2 between the temperature sensor (116) and an outer peripheral edge of an air suction port (111) is smaller than a shortest distance D1 between the temperature sensor (116) disposed inside a casing (33) to detect temperature of suction air and an outer peripheral edge of the ventilation port (115).SELECTED DRAWING: Figure 5

Description

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

As an indoor unit of an air conditioner (hereinafter, also simply referred to as an indoor unit), there is known a ceiling-mounted type that includes a casing having a suction port that sucks indoor air and an outlet that blows conditioned air into the room. (For example, see Patent Document 1). In this indoor unit, an opening for ventilation is provided in the casing so that air that is not air-conditioned or outdoors such as the ceiling may be introduced (ventilated) into the casing.

Japanese Utility Model Publication No. 62-124413

When a temperature sensor that detects the intake temperature of indoor air is provided in the indoor unit, the temperature of outdoor air (for example, outdoor air) introduced into the casing through the ventilation opening may be detected depending on the position of the temperature sensor. is there. Then, the detected temperature of the indoor air becomes inaccurate.

An object of the present disclosure is to suppress an inaccurate detected temperature of intake air in a ceiling-mounted indoor unit including a ventilation port.

In the aspect of the present disclosure, the term indicating the direction and the position indicating the direction of the constituent element of the indoor unit indicates the direction and the position in a state where the indoor unit is installed in a specific space to be air-conditioned.

The first aspect of the present disclosure is
An indoor unit of a ceiling-mounted air conditioner that air-conditions a specific space is assumed.

The indoor unit of this ceiling-mounted air conditioner
A box-shaped casing (33),
An air blower (32) arranged in the casing (33),
A heat exchanger (31) arranged on the leeward side of the air blower (32),
An air suction port (111) provided in the casing (33) for sucking air in the space;
An air outlet (75) provided in the casing (33) for blowing air into the space;
A ventilation port (115) formed in the casing (33) for introducing air outside the space into the casing (33);
A temperature sensor (116) for detecting the temperature of air sucked from the air suction port (111),
The ventilation port (115) and the temperature sensor (116) are provided on the windward side of the heat exchanger (31),
From the shortest distance D1 between the temperature sensor (116) and the outer peripheral edge (115a) of the ventilation port (115), the temperature sensor (116) and the outer peripheral edge (111a) of the air suction port (111) are The shortest distance D2 is small.

In the first aspect, since D2 is smaller than D1, the temperature sensor (116) is arranged at a position closer to the outer peripheral edge (111a) of the air suction opening (111) than the outer peripheral edge (115a) of the ventilation opening (115). It In the first aspect, an air flow that is sucked into the blower device (32) through the air suction port (111) and an air flow that is sucked into the blower device (32) through the ventilation port (115) are formed. However, since D2 is smaller than D1, the temperature sensor (116) sucks air from the air suction port (111) into the blower device (32) rather than the air sucked into the blower device (32) through the ventilation port (115). It is easy to detect the temperature of indoor air. Therefore, it is possible to prevent the detected temperature of the intake air from becoming inaccurate.

A second aspect of the present disclosure is, in the first aspect,
The casing (33) includes a top plate (97), a bottom plate (98), and a side portion (34) arranged between the top plate (97) and the bottom plate (98),
The side part (34) of the casing (33) is provided between the front panel (94), the rear panel (93) facing the front panel (94), and between the front panel (94) and the rear panel (93). Having a plurality of horizontal panels (95, 96),
The back panel (93) is characterized in that the air suction port (111) is formed.

In the second aspect, the ventilation port (115) includes a top plate (97), a bottom plate (98) and side portions (34) (a rear panel (93), a front panel (94) and a lateral panel (95, 96). ). Also in the second mode, since D2 is smaller than D1, the temperature sensor (116) blows air from the air suction port (111) rather than the air sucked into the air blower (32) through the ventilation port (115). It is easy to detect the temperature of the indoor air drawn into (32). Therefore, the box-shaped casing (33) has the top plate (97), the bottom plate (98), and the side part (34), and the side part (34) has the rear panel (93), the front panel (94), and the lateral surface. In the indoor unit configured to have the panels (95, 96), it is possible to prevent the detected temperature of the intake air from becoming inaccurate.

According to a third aspect of the present disclosure, in the second invention,
The ventilation port (115) is characterized by being formed in one of the two lateral panels (95, 96) located on both sides of the rear panel (93) of the casing (33).

In the third aspect, the air inlet (111) is formed in the rear panel (93), and the ventilation port (115) is provided in one of the two lateral panels (95, 96) located on both sides of the rear panel (93). In the indoor unit in which is formed, it is possible to prevent the detected temperature of the intake air from becoming inaccurate.

A fourth aspect of the present disclosure is, in the third aspect,
The plurality of lateral panels (95, 96) are a first lateral panel (95) and a second lateral panel (96) that face each other.

In the fourth aspect, the plurality of lateral panels (95, 96) are a first lateral panel (95) and a second lateral panel (96) that face each other, and the ventilation opening (115) has a first lateral panel. It is formed on one of the face panel (95) and the second lateral panel (96). In the fourth aspect, the air suction port (111) is formed in the back panel (93), and the ventilation port (115) is provided in one of the first lateral panel (95) and the second lateral panel (96) facing each other. In the indoor unit in which) is formed, it is possible to prevent the detected temperature of the intake air from becoming inaccurate.

A fifth aspect of the present disclosure is the third or fourth aspect,
The temperature sensor (116) is characterized in that it is closer to the other than one of the two lateral panels (95, 96) located on both sides of the rear panel (93) of the casing (33).

In the fifth aspect, the temperature sensor (116) is provided at a position closer to the other than one of the two lateral panels (95, 96) located on both sides of the rear panel (93) of the casing (33). In other words, the temperature sensor (116) is provided at a position closer to the horizontal panel (95) where the ventilation port (115) is not formed than the horizontal panel (96) where the ventilation port (115) is formed. Therefore, the temperature sensor (116) is displaced from the center of the casing (33) in the width direction (left-right direction) in the direction away from the ventilation port (115). Therefore, the temperature sensor (116) can easily detect the temperature of the air that has flowed into the casing (33) from the air suction port (111), and can detect the temperature of the air that has flowed into the casing (33) from the ventilation port (115). A difficult configuration can be easily realized.

A sixth aspect of the present disclosure is, in the fifth aspect,
Inside the casing (33), an electrical component box (65) accommodating a control board (66) is arranged closer to one side than the other of the two lateral panels (95, 96) of the casing (33). Was
The temperature sensor (116) is connected to the control board (66).

In the sixth aspect, the temperature sensor (116) easily detects the temperature of the air that has flowed into the casing (33) from the air suction port (111), and has flowed into the casing (33) from the ventilation port (115). It is difficult to detect the air temperature. Moreover, since the electric component box (65) is arranged near the other lateral panel, the control board (66) and the temperature sensor (116) can be arranged at close positions. As a result, it becomes easy to connect the temperature sensor (116) to the control board (66) in the electrical component box (65).

A seventh aspect of the present disclosure is the method according to any one of the second to sixth aspects,
A shortest distance D3 between the horizontal panel (95) closest to the temperature sensor (116) and the temperature sensor (116) is smaller than the shortest distance D1.

In the seventh aspect, both D2 and D3 are smaller than D1. Therefore, the temperature sensor (116) is arranged closer to the air suction port (111) than the ventilation port (115) and closer to the lateral panel (95) where the ventilation port (115) is not formed. In the seventh aspect, similarly to the case where the ventilation port (115) is formed in the lateral panel (95, 96), the surface other than the lateral panel (95, 96) (for example, the top plate (97)). Even if the temperature sensor (116) is formed on the air intake port (111), the temperature sensor (116) is arranged near the horizontal panel (95) where the ventilation port (115) is not formed, and the temperature sensor (116) is located away from the ventilation port (115). ), it is possible to prevent the detected temperature of the intake air from becoming inaccurate.

An eighth aspect of the present disclosure is the method according to any one of the second to seventh aspects,
A plurality of the air blowers (32) are arranged between the two lateral panels (95, 96) arranged on both sides of the back panel (93) in a direction intersecting with the air flow direction. Has fans (32a-32d),
The plurality of fans (32a to 32d) have the shortest distance between the first fan (32a) and the temperature sensor (116) that have the shortest shortest distance from the peripheral portion of the ventilation port (115). Includes a shortest second fan (32b).

In the eighth aspect, the air sucked into the first fan (32a) is likely to be the air that has passed through the ventilation port (115), and the air sucked into the second fan (32b) passes through the air suction port (111). It is easy to get through the air. Here, since the temperature sensor (116) is arranged closer to the air suction port (111) than the ventilation port (115) and closer to the second fan (32b), the temperature sensor (116) is arranged at the air suction port (111). ), it is easy to detect the temperature of the air flowing into the casing (33). Therefore, it becomes easy to suppress that the detected temperature of the intake air becomes inaccurate.

A ninth aspect of the present disclosure is the method according to any one of the first to eighth aspects,
The casing (33) has a first casing (51) and a second casing (101) attached to the first casing (51),
The blower device (32) and the heat exchanger (31) are housed in the first casing (51),
The ventilation port (115) is formed in the second casing (101).

In the ninth aspect, since the ventilation port (115) is formed in the second casing (101), only the second casing (101) can be removed for maintenance when the ventilation port (115) is maintained. it can. Therefore, maintenance of the ventilation port (115) becomes easy.

FIG. 1 is a refrigerant circuit diagram schematically showing the configuration of an air conditioner. FIG. 2 is a perspective view of the indoor unit of the embodiment as viewed from diagonally above and front. FIG. 3 is a sectional view taken along line III-III in FIG. FIG. 4 is a schematic diagram showing a device arrangement inside the indoor unit. FIG. 5 is a layout diagram showing a positional relationship between the temperature sensor and the ventilation port in the indoor unit. FIG. 6 is a layout diagram showing the positional relationship between the temperature sensor and the ventilation port in the indoor unit of Modification 1. FIG. 7 is a layout diagram showing a positional relationship between the temperature sensor and the ventilation port in the indoor unit of the modified example 2. FIG. 8 is a vertical cross-sectional view of an indoor unit according to Modification 7. FIG. 9 is a schematic diagram showing a device arrangement inside the indoor unit of FIG. 8.

An embodiment will be described. The air conditioner (10) of the present embodiment includes an indoor unit (30) and an outdoor unit (20) connected to the indoor unit (30), and performs air conditioning of an indoor space that is a specific air-conditioned space. .. In the present specification, "top", "bottom", "right", "left", "front (front)", "back (rear)", "lateral", "top plate", "bottom plate". , "Sides" and the like indicating directions and positions mean directions and positions when the indoor unit (30) in the installed state is viewed from the front side (front side).

-Air conditioner-
The air conditioner (10) will be described with reference to FIG. 1.

As shown in FIG. 1, the air conditioner (10) includes an indoor unit (30) and an outdoor unit (20). In the air conditioner (10), the compressor (21), the four-way switching valve (22), the outdoor heat exchanger (23), the expansion valve (24), and the indoor heat exchanger (31) are connected by a refrigerant pipe, A refrigerant circuit (11) that performs a vapor compression refrigeration cycle is configured.

The refrigerant circuit (11) includes an outdoor circuit (12), an indoor circuit (13), a liquid-side first communication pipe (14), and a gas-side second communication pipe (15). The first communication pipe (14) is connected to the first shutoff valve (16) of the outdoor circuit (12) and the first pipe joint (18) of the indoor circuit (13). The second communication pipe (15) is connected to the second closing valve (17) of the outdoor circuit (12) and the second pipe joint (19) of the indoor circuit (13).

<Schematic configuration of indoor unit>
The indoor unit (30) is installed in the indoor space, and includes an indoor heat exchanger (31), an indoor air blower (32), and a drain pan (35) not shown in FIG. 1 (FIG. 3). See) and.

The indoor heat exchanger (31) exchanges heat between the refrigerant flowing inside and the indoor air supplied by the indoor blower (32). The indoor heat exchanger (31) is composed of, for example, a fin-and-tube heat exchanger. The indoor heat exchanger (31) constitutes the heat exchanger of the present disclosure.

The indoor blower (32) is for supplying indoor air to the indoor heat exchanger (31) and further supplying the air passing through the indoor heat exchanger (31) to the indoor space. The indoor air blower (32) constitutes the air blower of the present disclosure.

<Schematic configuration of outdoor unit>
The outdoor unit (20) is installed outdoors, and includes a compressor (21), a four-way switching valve (22), an outdoor heat exchanger (23), an outdoor fan (25), and an expansion valve. (24), a liquid-side first closing valve (26), and a gas-side second closing valve (27).

The compressor (21) sucks the low-pressure gas refrigerant flowing out of the indoor heat exchanger (31) and the outdoor heat exchanger (23) functioning as an evaporator, and compresses the low-pressure gas refrigerant to compress the high-temperature high-pressure gas. The refrigerant is discharged. The high-pressure gas refrigerant discharged by the compressor (21) flows into the indoor heat exchanger (31) and the outdoor heat exchanger (23) that function as a radiator.

The four-way switching valve (22) is for reversibly switching the flow of the refrigerant in the refrigerant circuit (11). Specifically, in the four-way switching valve (22), the indoor heat exchanger (31) functions as an evaporator and the air conditioner (10) performs the cooling operation in the first state (the state shown by the solid line in FIG. 1). And the indoor heat exchanger (31) serves as a radiator and can be switched to the second state (state shown by the broken line in FIG. 1) for the air conditioning apparatus (10) to perform the heating operation.

The outdoor heat exchanger (23) exchanges heat between the refrigerant flowing inside and the outdoor air supplied by the outdoor fan (25). The outdoor heat exchanger (23) is composed of, for example, a fin-and-tube heat exchanger.

The outdoor fan (25) is for supplying outdoor air to the outdoor heat exchanger (23).

The expansion valve (24) is for decompressing the refrigerant that has flowed out of the indoor heat exchanger (31) and the outdoor heat exchanger (23) that function as radiators. The expansion valve (24) is, for example, an electronic expansion valve whose opening can be adjusted.

<Specific configuration of indoor unit>
The indoor unit (30) of the present embodiment is a ceiling-suspended type and is installed near the ceiling of the indoor space. Here, the indoor unit (30) of the present embodiment will be described with reference to FIGS. 2 to 5 as appropriate.

As shown in FIGS. 2 to 4, the indoor unit (30) is formed in a rectangular parallelepiped shape as a whole. This indoor unit (30) includes one main body unit (50), one additional unit (100), and a pair of decorative covers (91, 92). The additional unit (100) is formed with an air suction port (111) for sucking the air in the indoor space into the additional unit (100), and the main unit (50) receives air from the additional unit (100). An air inlet (60) that flows into the body unit (50) is formed. The main unit (50) is formed with an air outlet (75) for blowing the conditioned air that has passed through the indoor heat exchanger (31) toward the front of the indoor unit (30) and supplying it to the indoor space. ..

As will be described later, the main body unit (50) has a first casing (51), and the additional unit (100) has a second casing (101). The casing (33) of the indoor unit (30) of the present embodiment is configured by the first casing (51) and the second casing (101) which are separate bodies.

The casing (33) has a frame (not shown), a top plate (97), a side part (34), and a bottom plate (98). In this embodiment, the side (34) has a four sided panel. In the casing (33), a rear panel (93) which is a side portion (34) provided with an air suction port (111) and a front panel (which is a side portion (34) provided with an air outlet (75) ( 94). The casing (33) has left and right lateral panels (95, 96). The "left and right lateral panels (95, 96)" here include the lateral panel of the first casing (51) and the lateral panel of the second casing (101), respectively. The horizontal panels (95, 96) are a right panel (first horizontal panel) (95) located on the right side and a left panel (second horizontal surface) located on the left side when the indoor unit (30) is installed. Panel) (96). The top plate (97) of the casing (33) is a plate-shaped member that constitutes the upper surface of the casing (33) when the indoor unit (30) is installed. The bottom plate (98) of the casing (33) is a plate-shaped member that constitutes the lower surface of the casing (33) when the indoor unit (30) is installed.

<Main unit>
The body unit (50) has a rectangular parallelepiped first casing (51). In FIG. 4, in this body unit (50), the back plate (56) is provided with the air inlet (60), and the front panel (94) facing the back plate (56) is provided with the air outlet (75). Is provided. An air passage (61) extending from the air inlet (60) to the air outlet (75) is formed inside the body unit (50). The indoor heat exchanger (31), the indoor blower (32), and the drain pan (35) are housed in the air passageway (61) in the main body unit (50). In the air passage (61), the indoor heat exchanger (31) is arranged on the leeward side of the indoor blower (32) in the air flow direction formed by the indoor blower (32).

The indoor heat exchanger (31) is provided so as to extend in the left-right direction of the body unit (50). As shown in FIG. 4, the indoor heat exchanger (31) has a configuration in which two heat exchange surfaces are arranged at an angle to each other so as to have an L-shape inclined in a side view.

As shown in FIG. 4, in this example, the indoor blower (32) has four indoor fans (32a to 32d) provided side by side in the left-right direction of the casing body (31). These indoor fans (32a to 32d) are arranged between the two lateral panels (95, 96) in a direction intersecting with the air flow direction. The indoor fans (32a to 32d) are connected to the fan motor (32e) by a common shaft (32f) and are driven by the fan motor (32e).

The body unit (50) is provided with an electrical component box (65). The electrical component box (65) is formed in a box shape having a substantially rectangular parallelepiped shape. A printed wiring board (66) that is a control board is housed in the electrical component box (65).

The drain pan (35) is arranged inside the first casing (51) and is located above the bottom plate (98). The drain pan (35) is made of foamed resin and receives drain water (condensed water) generated in the indoor heat exchanger (31). As shown in FIGS. 3 and 4, the drain pan (35) has a water receiving portion (36) which is rectangular in a plan view for receiving drain water, and a rising portion formed at an outer edge of the water receiving portion (36). A part (37).

As shown in FIG. 3, an outlet passage (73) is formed in the main body unit (50) on the downstream side of the heat exchanger (31) in the air flow direction. The outlet passage (73) is a passage that extends obliquely downward as a whole from the indoor heat exchanger (31) toward the air outlet (75), and has an air outlet (75 at the downstream end in the air flow direction). ) Has been formed. The blowout passageway (73) is entirely arranged downstream of the rising portion (37) which is the outer edge of the drain pan (35) in the air flow direction.

The air outlet (75) is provided with an airflow direction adjusting blade (85) including a plurality of (four in the present embodiment) blade members (86) made of synthetic resin. Each blade member (86) is an elongated rectangular plate member. The blade members (86) are arranged so as to cross the air outlet (75) in the left and right directions in a posture in which the longitudinal direction thereof is substantially horizontal (see FIG. 2). The four blade members (86) are arranged at equal intervals in the vertical direction. Each blade member (86) is rotatable within a predetermined angle range about a rotation axis extending along the longitudinal direction thereof. The wind direction adjusting blade (85) closes the air outlet (75) when the indoor unit (30) is not in operation. The term "closed" as used herein includes a state in which a certain amount of gap is formed.

When each blade member (86) is driven by a wind direction adjusting motor (not shown), the angle of each blade member (86) changes. Each blade member (86) guides the air blown out from the blowout passageway (73). Therefore, when the angle of each blade member (86) changes, the direction of the air blown out from the blowing passage (73) changes in the vertical direction. The wind direction adjusting blade (85) is configured to be able to adjust the wind direction of the air flowing out of the blowout passageway (73) from a predetermined angle below the horizontal to a predetermined angle above the horizontal with the indoor unit (30) installed. ing.

<Additional unit>
The configuration of the additional unit (100) will be described with reference to FIGS. 3 and 4. As shown in the figure, the additional unit (100) includes a second casing (101) and a discharge part (102).

The outer shape of the second casing (101) is formed into a horizontally long rectangular parallelepiped shape, and is attached to the back surface of the main body unit (50). The second casing (101) has the air suction port (111) for sucking air into the inside, and a ventilation port (112) through which air flows from the second casing (101) to the first casing (51). .. The air suction port (111) is provided with a filter (not shown).

The discharge part (102) is housed in the second casing (101). The discharge part (102) is provided to purify the air flowing in the second casing (101) by the discharge in which low-temperature plasma containing active species is generated. Although not shown, the additional unit is provided with an electrical component box containing a control board for controlling the operation of the discharge unit (102), separately from the electrical component box (65) of the main unit (50). There is.

The left casing (96) of the second casing (101) has a ventilation port (115) for introducing outdoor air into the additional unit (100) and the main body unit (50). The outdoor air is air whose temperature is not controlled, such as outdoor air or air above the ceiling. A duct (not shown) that introduces outdoor air into the internal space of the casing (33) is connected to the ventilation port (115) to ventilate the inside of the casing (33).

<Intake air temperature detection structure>
Inside the first casing (51), a temperature sensor (116) for detecting the temperature of the suction air sucked from the air suction port (111) is provided. The temperature sensor (116) of this embodiment has a temperature detection unit (116a) as a part of the temperature sensor (116). The temperature sensor (116) is a sensor whose electric resistance changes when the temperature of the detection target changes, and in FIG. 4, the main body portion and the temperature detection portion (116a) are each simply shown as a rectangle. In the present disclosure, the “temperature sensor (116)” refers to one that detects the temperature of air. The temperature sensor (116) is connected to a wiring (not shown) that is a component different from the temperature sensor (116).

As shown in FIG. 5, from the shortest distance D1 between the temperature sensor (116) (specifically, the temperature detection unit (116a)) and the outer peripheral edge (115a) of the ventilation port (115), the temperature sensor (116) (Specifically, the shortest distance D2 between the temperature detector (116a)) and the outer peripheral edge (111a) of the air suction port (111) is small. The shortest distances D1 and D2 correspond to the lengths of arrows D1 and D2 in FIG. If expressed roughly, the temperature sensor (116) is closer to the air intake port (111) than the ventilation port (115).

Further, between the temperature sensor (116) and the right panel (95) which is closest to the temperature sensor (116) (specifically, the temperature detecting section (116a)) and in which the ventilation port (115) is not formed. The shortest distance D3 is smaller than the shortest distance D1.

The electrical component box (65) is arranged at a position closer to the right panel (95) than the left panel (96). The temperature sensor (116) is attached to the electrical component box (65) and is connected to the printed wiring board (66) in the electrical component box (65) by the above wiring. With this arrangement, the temperature sensor (116) is located closer to the right panel (95) than to the left panel (96) and is away from the ventilation port (115).

As described above, the four indoor fans (32a to 32d) are arranged between the right panel (95) and the left panel (96) in the left-right direction that intersects substantially perpendicularly to the air flow direction. The shortest distances between the four indoor fans (32a to 32d) and the temperature sensor (116) are different, and the shortest distances between the four indoor fans (32a to 32d) and the temperature sensor (116) are also respectively. different.

In this embodiment, the four indoor fans (32a to 32d) include a first indoor fan (32a) and a second indoor fan (32b). The first indoor fan (32a) is closest to the left panel (96) among the four indoor fans (32a to 32d) and has the shortest distance () from the peripheral portion (115a) of the ventilation port (115) ( The length of the dashed arrow D4 in the figure) is the shortest. The second indoor fan (32b) is closest to the right panel (95) among the four indoor fans (32a to 32d) and has the shortest shortest distance from the temperature sensor (116).

The distance D2 between the outer peripheral edge (111a) of the air suction port (111) and the temperature sensor (116) is greater than the distance D1 between the outer peripheral edge (115a) of the ventilation port (115) and the temperature sensor (116). The distance between the temperature sensor (116) and the second indoor fan (32b) is shorter than the distance between the indoor fan (32) and the other indoor fan (32). The air flowing into the casing (33) from the suction port (111) passes through the temperature sensor (116) and is sucked into the second indoor fan (32b). Therefore, an air path from the air inlet (111) to the second indoor fan (32b) through the temperature sensor (116) and an air path from the ventilation opening (115) to the first indoor fan (32a). Are likely to be different.

The ventilation port (115) and the temperature sensor (116) may be arranged so that the arrangement is left-right reversed from that of this embodiment.

<Cosmetic cover>
The decorative covers (91, 92) are elongated rectangular parallelepiped box-shaped members. The makeup cover (91, 92) is open at one of the side surfaces on the long side and the back surface. The length of the decorative cover (91, 92) is substantially equal to the length from the back surface of the additional unit (100) to the front surface of the main body unit (50).

The decorative covers (91, 92) are attached to the main body unit (50) with their open side surfaces facing the casing (33) side, and cover the side surfaces of the main body unit (50) and the additional unit (100). The right decorative cover (91) arranged on the right side of the casing (33) covers the right panel (95) of the casing (33). The left decorative cover (92) arranged on the left side of the casing (33) covers the left panel (96) of the casing (33).

-Driving operation-
The air conditioner (10) selectively performs cooling operation and heating operation.

In the cooling operation, the four-way switching valve (22) is set to the first state, and the refrigerant circulates in the refrigerant circuit (11). The outdoor heat exchanger (23) functions as a radiator, and the indoor heat exchanger (31) functions as an evaporator. The indoor unit (30) cools the air sucked from the indoor space in the indoor heat exchanger (31) and blows the cooled air into the indoor space.

In the heating operation, the four-way switching valve (22) is set to the second state, and the refrigerant circulates in the refrigerant circuit (11). The indoor heat exchanger (31) functions as a radiator, and the outdoor heat exchanger (23) functions as an evaporator. The indoor unit (30) heats the air sucked from the indoor space in the indoor heat exchanger (31) and blows the heated air into the indoor space.

<Detection of intake air temperature>
In this embodiment, the air that has passed through the suction port (111) is sucked into each of the four indoor fans (32a to 32d). On the other hand, as described above, the air path from the ventilation port (115) to the first indoor fan (32a) and the air path from the air suction port (111) to the second indoor fan (32b) are different. Therefore, most of the air that has passed through the ventilation port (115) is sucked by the first fan (32a) and is hardly sucked by the second fan (32b) as indicated by arrow D4. Further, since the temperature sensor (116) is arranged closer to the air suction port (111) than the ventilation port (115), the temperature sensor (116) is arranged from the ventilation port (115) to the first fan (32a). It is difficult to detect the temperature of the outdoor air that is sucked into the room, and it is easy to detect the temperature of the room air that is drawn into the second indoor fan (32b) from the air suction port (111). Therefore, the temperature of the intake air is detected with high accuracy by the temperature sensor (116).

-Effect of embodiment-
In this embodiment, the indoor unit (30) includes a ventilation port (115) formed in the casing (33) for introducing outdoor air into the casing (33) and air sucked from the air suction port (111). And a temperature sensor (116) for detecting the temperature of the indoor heat exchanger (31) in the air flow direction. Then, from the shortest distance D1 between the temperature sensor (116) and the outer peripheral edge (115a) of the ventilation port (115), the shortest distance between the temperature sensor (116) and the outer peripheral edge (111a) of the air suction port (111). D2 is small. Further, the shortest distance D3 between the temperature sensor (116) and the right panel (95) which is the lateral panel closest to the temperature sensor (116) is smaller than the shortest distance D1.

In this embodiment, the casing (33) includes a top plate (97), a bottom plate (98), and a side portion (34) disposed between the top plate (97) and the bottom plate (98). The suction port (111) is formed in the back panel (93) of the side part (34). The side part (34) facing the back panel (93) is defined as the front panel (94), and the side part (34) excluding the back panel (93) and the front panel (94) is a lateral panel of the casing (33). (95, 96).

Here, in a case where a temperature sensor that detects the intake temperature of indoor air is provided in an indoor unit where a ventilation port is provided in the casing, depending on the position of the temperature sensor, the outdoor unit introduced into the casing through the ventilation port (115) may be used. There is a risk of detecting the temperature of air (for example, outdoor air), in which case the detected temperature of indoor air will be inaccurate.

In the present embodiment, in the indoor unit (30) having the box-shaped casing (33) provided with the back panel (93), the front panel (94) and the left and right lateral panels (95, 96), the temperature sensor (116). ) And the outer peripheral edge (115a) of the ventilation port (115), the shortest distance D2 between the temperature sensor (116) and the outer peripheral edge (111a) of the air suction port (111) is smaller. In other words, the temperature sensor (116) is arranged at a position closer to the outer peripheral edge (111a) of the air suction port (111) than the outer peripheral edge (115a) of the ventilation port (115). The temperature sensor (116) is located closer to the air inlet (111) than the vent (115), and is located near the right panel (57,109) where the vent (115) is not formed. To be done.

Therefore, in the path of the air sucked into the fans (32a to 32d) through the air suction port (111) and the path of the air sucked into the fans (32a to 32d) through the ventilation port (115), the temperature sensor ( The air passing through 116) is likely to be mostly indoor air sucked from the air suction port (111). Therefore, the temperature sensor is less likely to detect the temperature of the air sucked through the ventilation port (115), and it is possible to prevent the detected temperature of the sucked air from becoming inaccurate.

In the present embodiment, the temperature sensor (116) is arranged closer to the right panel (95) where the ventilation port (115) is not formed than the left panel (96) where the ventilation port (115) is formed. There is. According to this configuration, the distance from the ventilation port (115) to the temperature sensor (116) is longer than that in the configuration in which the temperature sensor (116) is located at the center of the casing (33) in the width direction. Therefore, it is difficult for the air sucked from the ventilation port (115) to reach the temperature sensor (116). Therefore, it becomes difficult for the temperature sensor (116) to detect the temperature of the air sucked from the ventilation port (115). Conversely, the temperature of the indoor air sucked from the air suction port (111) is detected by the temperature sensor (116). ) Makes it easier to detect.

In this embodiment, the electrical component box (65) containing the printed wiring board (66) is arranged near the right panel (95) in which the ventilation port (115) is not formed, and the temperature sensor (116) is installed. It is connected to the printed wiring board (66). According to this configuration, the air flowing into the casing (33) from the air suction port (111) easily reaches the temperature sensor (116), and the air flowing into the casing (33) from the ventilation port (115) is heated to the temperature. It becomes difficult to reach the sensor (116). Moreover, in this embodiment, the temperature sensor (116) and the electrical component box (65) are both arranged near the right panel (95), and the distance between the temperature sensor (116) and the electrical component box (65) is short. , It becomes easy to connect the temperature sensor (116) to the printed wiring board (66) in the electrical component box (65).

In this embodiment, a plurality of indoor fans (32a to 32d) including a first fan (32a) and a second fan (32b) are provided. The shortest distance between the first fan (32a) and the peripheral edge of the ventilation port (115) is the shortest, and the shortest distance between the second fan (32b) and the temperature sensor (116) is the shortest. .. According to this configuration, the air sucked into the first fan (32a) is likely to be the air that has passed through the ventilation port (115), and the air sucked into the second fan (32b) is the air suction port (111) and Air that has passed through the temperature sensor (116) is likely to be generated. Then, since the temperature of the room air sucked from the air suction port (111) is easily detected by the temperature sensor (116), it becomes easy to prevent the detected temperature of the suction air from becoming inaccurate.

In the present embodiment, the casing (33) has a first casing (51) and a second casing (101) mounted on the first casing (51). The indoor fan (32a-32d) and the said heat exchanger (31) are accommodated in the 1st casing (51). The functional component (102) is housed in the second casing (101). The ventilation port (115) is formed in the second casing (101).

In this embodiment, since the ventilation port (115) is formed in the second casing (101), it is possible to remove only the second casing (101) and perform maintenance when maintaining the ventilation port (115). it can. Therefore, maintenance of the ventilation port (115) becomes easy.

-Modification of Embodiment 1-
<Modification 1>
As shown in FIG. 6, the ventilation port (115) may be formed in the top plate (97) instead of being formed in the left panel (96). Also in this modification 1, the temperature sensor (116) is located far from the outer peripheral edge (115a) of the ventilation port (115) and near the outer peripheral edge (111a) of the air suction port (111). Specifically, the magnitude relationship between the distances indicated by D1, D2, and D3 described in the above embodiment is set similarly to the above embodiment.

Therefore, also in the first modification, the outdoor air flowing into the casing (33) from the ventilation port (115) is unlikely to reach the temperature sensor (116), and the suction port (111) to the inside of the casing (33). The air in the indoor space that has flowed into the temperature sensor can easily reach the temperature sensor (116). Therefore, it is possible to prevent the detected temperature of the intake air from becoming inaccurate.

<Modification 2>
As shown in FIG. 7, the ventilation port (115) may be formed in the rear panel (93) instead of being formed in the left panel (96). In the second modification, the temperature sensor (116) is arranged far from the left panel (96) and close to the right panel (95). The ventilation port (115) is formed on the rear panel (93) near the left panel (96), and the distance from the right panel (95) to the ventilation port (115) is from the left panel (96) to the ventilation port (115). ) Farther than. The temperature sensor (116) is located closer to the outer peripheral edge of the air suction port (111) than the outer peripheral edge (115a) of the ventilation opening (115). Specifically, the magnitude relationship between the distances indicated by D1, D2, and D3 described in the above embodiment is set similarly to the above embodiment.

Also in this modified example 2, the outdoor air flowing into the casing (33) from the ventilation port (115) is easily sucked into the first fan (32a) along the arrow D4, and the temperature sensor (arrow D1) 116) is difficult to reach. On the contrary, the air in the indoor space that has flowed into the casing (33) from the suction port (111) easily reaches the temperature sensor (116) along the arrow D2. Therefore, it is possible to prevent the detected temperature of the intake air from becoming inaccurate.

<Modification 3>
The temperature sensor (116) and the ventilation port (115) are not limited to the arrangement in the positional relationship of the above-described embodiment, modification 1 and modification 2, and may be other arrangements. For example, the temperature sensor (116) does not necessarily have to be provided in the electrical component box (65), and may be disposed apart from the electrical component box (65). However, the temperature sensor (116) is arranged at a position closer to the suction port (111) than the ventilation port (115).

Even with this configuration, it is possible to prevent the detected temperature of the intake air from becoming inaccurate, as in the above-described embodiment and each modification.

<Modification 4>
In the above embodiment, the temperature sensor (116) is arranged at a position closer to the right panel (95) where the ventilation port (115) is not formed than the left panel (96) where the ventilation port (115) is formed. However, other arrangements may be used. For example, the temperature sensor (116) is arranged at the center of the right panel (95) and the left panel (96) and near the bottom plate (98), and the ventilation port (115) is arranged at the left panel (96) (or The right panel (95) may be formed at a position close to the top plate (97). In other words, the temperature sensor (116) and the ventilation port (115) are arranged vertically apart from each other in the casing (33). Also in this case, the air suction port (111) is formed in the rear panel (93), for example, and the temperature sensor (116) is arranged near the outer peripheral edge (111a) of the air suction port (111).

Even with this configuration, it is possible to prevent the detected temperature of the intake air from becoming inaccurate, as in the above-described embodiment and each modification.

<Modification 5>
In the above embodiment, the plurality of indoor fans (32a to 32d) are arranged inside the first casing (51), and the plurality of indoor fans (32a to 32d) are connected to the peripheral portion (116a) of the ventilation port (115). A first fan (32a) with the shortest distance between the two and a second fan (32b) with the shortest distance between the temperature sensor (116) are included. However, the number of indoor fans is not limited to a plurality.

Specifically, in the configuration having one indoor fan (32), the temperature sensor (116) is more than the shortest distance D1 between the temperature sensor (116) and the outer peripheral edge (115a) of the ventilation port (115). The shortest distance D2 from the outer peripheral edge (111a) of the air suction port (111) may be reduced. Even with this configuration, it is possible to prevent the detected temperature of the intake air from becoming inaccurate, as in the above-described embodiment and each modification.

<Modification 6>
In the above embodiment, the shortest distance D1 between the temperature sensor (116) and the outer peripheral edge (115a) of the ventilation port (115), the outer peripheral edge (111a) of the temperature sensor (116) and the air suction port (111), and Of the temperature sensor (116) and the shortest distance D3 between the temperature sensor (116) and the right panel (95) closest to the temperature sensor (116) such that both D2 and D3 are smaller than D1. A sensor (116) is arranged. On the other hand, as long as the relationship that D2 is smaller than D1 is satisfied, the relationship that D3 is smaller than D1 may not be satisfied.

In short, in the temperature detection structure of the intake air of the present disclosure, the temperature sensor (116) and the air suction port are shorter than the shortest distance D1 between the temperature sensor (116) and the outer peripheral edge (115a) of the ventilation port (115). As long as the shortest distance D2 from the outer peripheral edge (111a) of (111) is smaller and the temperature sensor (116) detects the temperature of the air in the indoor space that has passed through the air suction port (111), other configurations are appropriate. You may change it.

<Modification 7>
In the modified example 7, as shown in FIGS. 8 and 9, in the main body unit (50), a portion where the blowout passageway (73) is provided on the downstream side of the indoor heat exchanger (31) in the air flow direction. Is a blow-out unit (70) separate from the main body unit (50). In this modification 7, the casing of the blowout unit (70) is mounted on the front surface of the casing of the main body unit (50).

The configuration of Modification 7 is the same as that of the first embodiment, except that the blowout unit (70) is separate from the main body unit (50). Particularly, from the shortest distance D1 between the temperature sensor (116) and the outer peripheral edge (115a) of the ventilation port (115), the shortest distance between the temperature sensor (116) and the outer peripheral edge (111a) of the air suction port (111). D2 is small. The shortest distance D3 between the temperature sensor (116) and the lateral panel (95, 96) closest to the temperature sensor (116) is smaller than the shortest distance D1.

Therefore, also in this modified example 7, as in the above-described embodiment, the temperature of the room air sucked from the air suction port (111) is easily detected by the temperature sensor (116), so that the detected temperature of the suction air is unsatisfactory. It is easy to suppress the accuracy.

<<Other Embodiments>>
The above embodiment may have the following configurations.

For example, in the above embodiment, the indoor unit (30) configured by combining the main body unit (50), the additional unit (100), and the makeup cover (91, 92) has been described, but the indoor unit (30) is A configuration in which the first casing (51) of the main unit (50) and the second casing (101) of the additional unit (100) are integrated, and the first casing (51) is provided with functional parts such as a discharge part. Good.

In the above-described embodiment and modification, the ventilation port (115) is formed only on one surface of the side part (34) of the casing (33) or only on the top plate (97), but it is optional. It may be formed on a plurality of surfaces such as two surfaces. Even in that case, the temperature sensor (116) and the air suction port (111) have an outer peripheral edge (111a) that is shorter than the shortest distance D1 between the temperature sensor (116) and the outer peripheral edge (115a) of the ventilation port (115). If the shortest distance D2 is smaller, the same effect as the above embodiment can be obtained.

In the above embodiment, the shape of the casing (33) is not limited to the rectangular parallelepiped shape, and may be a hexagonal or octagonal solid when seen in a plan view. When the casing (33) is not a rectangular parallelepiped, the total number of left and right side panels is three or more. Further, the aspect in which the front panel (94) and the rear panel (93) face each other is not limited to parallel, and the front panel (94) may be inclined, for example. Similarly, the aspect in which the side panels (34) face each other in the rectangular parallelepiped casing (33) is not limited to parallel.

In the indoor unit (30) having the ventilation port (115) of the present disclosure, the air sucked into the casing (33) from the air suction port (111) causes the indoor blower (32) and the indoor heat exchanger (31) to operate. In the structure in which the air passes through and is blown out from the air outlet (75), the outer peripheral edge of the air suction opening (111) is shorter than the shortest distance D1 between the outer peripheral edge (115a) of the ventilation opening (115) and the temperature sensor (116). It is sufficient that the shortest distance D2 between (111a) and the temperature sensor (116) is shorter, and it is not limited to the ceiling-suspended indoor unit.

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-described embodiments and modified examples may be appropriately combined or replaced as long as the functions of the object of the present disclosure are not impaired.

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

10 Air conditioner
30 Indoor unit
31 Indoor heat exchanger (heat exchanger)
32 Indoor air blower (air blower)
32a First indoor fan (first fan)
32b Second indoor fan (second fan)
33 casing
34 side
65 Electrical equipment box
66 Printed wiring board (control board)
75 Outlet
93 rear panel
94 front panel
95 Right panel (first horizontal panel)
96 Left panel (2nd lateral panel)
97 Top plate
98 Bottom plate
111 Suction port
111a outer edge
115 Ventilation port
115a outer edge
116 Temperature sensor
116a Temperature detector

The distance D2 between the outer peripheral edge (111a) of the air suction port (111) and the temperature sensor (116) is greater than the distance D1 between the outer peripheral edge (115a) of the ventilation port (115) and the temperature sensor (116). Is shorter, and the distance between the temperature sensor (116) and the second indoor fan (32b) is shorter than the distance between the other indoor fan (32), so that the air intake close to the temperature sensor (116) The air flowing from the mouth (111) into the casing (33) passes through the temperature sensor (116) and is sucked into the second indoor fan (32b). Therefore, an air path from the air inlet (111) to the second indoor fan (32b) through the temperature sensor (116) and an air path from the ventilation opening (115) to the first indoor fan (32a). Are likely to be different.

Claims (9)

An indoor unit of a ceiling-mounted air conditioner that air-conditions a specific space,
A box-shaped casing (33),
An air blower (32) arranged in the casing (33),
A heat exchanger (31) arranged on the leeward side of the air blower (32),
An air suction port (111) provided in the casing (33) for sucking air in the space;
An air outlet (75) provided in the casing (33) for blowing air into the space;
A ventilation port (115) formed in the casing (33) for introducing air outside the space into the casing (33);
A temperature sensor (116) for detecting the temperature of air sucked from the air suction port (111),
The ventilation port (115) and the temperature sensor (116) are provided on the windward side of the heat exchanger (31),
The shortest distance D1 between the temperature sensor (116) and the outer peripheral edge (115a) of the ventilation port (115) is the distance between the temperature sensor (116) and the outer peripheral edge (111a) of the air suction port (111). An indoor unit for a ceiling-mounted air conditioner, which is smaller than the shortest distance D2. In claim 1,
The casing (33) includes a top plate (97), a bottom plate (98), and a side portion (34) arranged between the top plate (97) and the bottom plate (98),
The side part (34) of the casing (33) is provided between the front panel (94), the rear panel (93) facing the front panel (94), and between the front panel (94) and the rear panel (93). Having a plurality of horizontal panels (95, 96),
An indoor unit for a ceiling-mounted air conditioner, wherein the air inlet (111) is formed in the back panel (93). In claim 2,
The ventilation port (115) is formed on one of the two lateral panels (95, 96) located on both sides of the rear panel (93) of the casing (33). Indoor unit of air conditioner. In claim 3,
An indoor unit for a ceiling-mounted air conditioner, wherein the plurality of horizontal panels (95, 96) are a first horizontal panel (95) and a second horizontal panel (96) facing each other. .. In Claim 3 or 4,
The temperature sensor (116) is closer to the other than one of the two lateral panels (95, 96) located on both sides of the rear panel (93) of the casing (33), and the ceiling-mounted air An indoor unit of a harmony device. In claim 5,
Inside the casing (33), an electrical component box (65) accommodating a control board (66) is arranged closer to one side than the other of the two lateral panels (95, 96) of the casing (33). Was
The indoor unit of a ceiling-mounted air conditioner, wherein the temperature sensor (116) is connected to the control board (66). In any one of Claims 2 to 6,
An indoor unit of a ceiling-mounted air conditioner characterized in that a shortest distance D3 between the horizontal panel (95) closest to the temperature sensor (116) and the temperature sensor (116) is smaller than the shortest distance D1. .. In any one of Claim 2 to 7,
The blower device (32) is arranged between the two lateral panels (95, 96) arranged on both sides of the back panel (93) so as to be aligned in a direction intersecting the air flow direction. Has fans (32a-32d),
The plurality of fans (32a to 32d) have the shortest distance between the first fan (32a) and the temperature sensor (116) that have the shortest shortest distance from the peripheral portion of the ventilation port (115). Includes a second fan (32b) having the shortest length, and an indoor unit for a ceiling-mounted air conditioner. In any one of Claim 1 to 8,
The casing (33) has a first casing (51) and a second casing (101) attached to the first casing (51),
The blower device (32) and the heat exchanger (31) are housed in the first casing (51),
The indoor unit of a ceiling-mounted air conditioner, wherein the ventilation port (115) is formed in the second casing (101).

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