JP2014215013A - Decorative laminate panel and air conditioner indoor unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent the generation of dew condensation on the surface of an air direction regulation blade in a portion overlapping with a closing member in a blowout flow path.SOLUTION: A decorative laminate panel (40) includes a guide plate (80) that is arranged between the closing member (36) and an air direction regulation blade (53) in the blowout flow path (43), and that is configured to guide air to an inner flow path (73).

Description

    The present invention relates to a decorative panel for an air conditioner and an indoor unit of an air conditioner including the decorative panel, and particularly relates to measures for preventing condensation of wind direction adjusting blades arranged in a blow-out flow path.

    Conventionally, an air conditioner that performs indoor cooling or heating is known. For example, the air conditioner disclosed in Patent Document 1 includes an indoor unit provided on a ceiling. The indoor unit includes an indoor fan, an indoor heat exchanger, a casing that houses a drain pan, and a decorative panel that is attached to a lower portion of the casing.

    In the indoor unit, when the indoor fan is operated, room air is sucked into the casing from the suction port of the decorative panel. After this air is cooled or heated by the indoor heat exchanger, it passes through the blowout flow path of the decorative panel and is supplied to the room. The blowing flow path is provided with a wind direction adjusting blade for adjusting the wind direction of the blown air. The air flowing through the blowout flow path is guided to the outside of the casing along the wind direction adjusting blade. That is, in the blowout flow path, the direction of the airflow flowing in the downward direction is changed to the diagonally outer side (horizontal side) by the airflow direction adjusting blade, and then supplied to the room.

JP 11-118234 A

    By the way, in an indoor unit of an air conditioner, a closing member such as a drain pan may be arranged so as to overlap vertically on a part of the upstream side of the blowout channel (a portion near the end in the longitudinal direction of the blowout channel). In this case, the air flow rate in the overlapping portion is reduced in the blowout flow path. On the other hand, in the blowout flow path, the wind direction adjusting blades are arranged so as to change the flow of the airflow in the horizontal direction as described above. For this reason, in the blowout flow path, the air flow rate tends to be smaller in the inner flow path near the center of the panel body than in the outer flow path near the outside of the panel body across the wind direction adjusting blade. Therefore, in the overlapping part of the drain pan in the blowout flow path, the flow rate of the air flowing through the inner flow path becomes extremely small.

    In this way, when air hardly flows through the inner channel of the overlapping portion of the drain pan in the outlet channel, the warm air in the room flows into the inner channel, and this warm air is cooled by the wind direction adjusting blade. As a result, there is a problem that air condenses on the surface of the airflow direction adjusting blade (the surface of the airflow direction adjusting blade facing the inner flow path) to cause dew condensation.

    This invention is made | formed in view of this point, The objective is to prevent that dew condensation generate | occur | produces on the surface of a wind direction adjustment blade | wing in the part which overlaps with the obstruction | occlusion member in a blowing flow path.

    1st invention makes object the decorative panel of the air conditioner provided in the lower part of the indoor unit main body (21) provided in a ceiling, and while a blowing flow path (43) is formed, this blowing flow path (43) A panel main body (41) partially covered by a closing member (36), and the blowout flow path (43) is connected to the inner flow path (73) near the center of the panel main body (41) and the panel main body ( 41) an air flow adjusting blade (53) that divides into an outer flow path (74) closer to the outside, and the air flow adjusting blade (53) that is disposed between the closing member (36) and the air flow adjusting blade (53) in the blowing flow path (43). And a guide plate (80) configured to guide the gas to the inner flow path (73).

    In the first invention, a part of the upstream side of the blowout channel (43) of the panel body (41) is covered with the closing member (36), so that this portion (hereinafter referred to as the overlapping portion of the blowout channel) The air flow is reduced. As a result, in the blowout flow path (43), the flow rate of the air flowing through the inner flow path (73) closer to the center of the panel body (41) with the airflow direction adjusting blade (53) interposed therebetween is particularly insufficient. However, in the present invention, the guide plate (80) is disposed between the closing member (36) and the wind direction adjusting blade (53), and the guide plate (80) guides air to the inner flow path (73). Therefore, the flow rate of the air which flows through the inner flow path (73) is ensured in the overlapping part of the blowing flow path (43). As a result, it is possible to prevent warm air in the room from flowing into the inner flow path (73), and as a result, it is possible to prevent the occurrence of condensation on the surface of the wind direction adjusting blade (53).

    On the other hand, in the blowout flow path (43), the outer flow path (74) closer to the outside of the panel body (41) with the wind direction adjusting blade (53) interposed therebetween is the main air flow. For this reason, a certain amount of air flow is ensured in the outer flow path (74) even in the overlapping portion of the blowout flow path (43). For this reason, due to the lack of the air flow rate in the outer flow path (74), there is almost no condensation on the back surface of the wind direction adjusting blade (53).

    According to a second aspect, in the first aspect, the guide plate (80) is configured to guide air only to the inner flow path (73).

    In the second invention, since the guide plate (80) guides the air only to the inner flow path (73) in the space covered by the closing member (36) in the blowing flow path (43), the inner flow path ( 73) ensures the flow rate of the air flowing through, and prevents the occurrence of dew condensation on the surface of the wind direction adjusting blade (53).

    In a third aspect based on the second aspect, the guide plate (80) is configured such that the air flow adjusting blade (53) is in the state where the air flow rate in the outer flow path (74) is maximized. A feature is that air is guided only to the path (73).

    In the third aspect of the invention, the wind direction adjusting blade (53) reaches a state where the air flow rate in the outer flow path (74) is maximized, so that the flow rate of air flowing through the outer flow path (74) increases, while the inner flow path ( 73) The flow rate of the air flowing through is likely to be insufficient. However, in the present invention, the guide plate (80) guides the air only to the inner flow path (73) in the space covered by the closing member (36) in the blowing flow path (43). For this reason, even when the wind direction adjusting blade (53) is in the above state, the flow rate of the air flowing through the inner flow path (73) is ensured, and condensation on the surface of the air direction adjusting blade (53) is prevented. it can.

    According to a fourth invention, in any one of the first to third inventions, the guide plate (80) is directed from the inner wall portion (50) of the outer flow path (74) toward the center side of the panel body (41). And the tip is separated from the inner wall surface (73a) of the inner flow path (73).

    The guide plate (80) of the fourth invention protrudes from the inner wall (50) of the outer flow path (74) toward the center of the panel body (41). Since the tip of the guide plate (80) is separated from the inner wall surface (73a) of the inner flow path (73), an opening through which air flows is formed between the inner wall surface (73a) and the tip of the guide plate (80). Is done. In the overlapping portion of the blowout flow path (43), the air above the guide plate (80) flows into the inner flow path (73) through this opening. Further, in the overlapping portion of the blowout flow path (43), the outer flow path (74) is blocked by the guide plate (80), so that air above the guide plate (80) may flow into the external flow path (74). It is blocked by the guide plate (80).

    According to a fifth aspect, in the fourth aspect, a curved plate portion (85) bent toward the downstream side of the blowing channel (43) is formed at a tip portion of the guide plate (80). It is characterized by.

    In the fifth aspect of the invention, the air above the guide plate (80) is guided to the inner flow path (73) along the curved plate portion (85) at the overlapping portion of the blowout flow path (43).

    According to a sixth aspect of the present invention, in any one of the first to fifth aspects, the guide plate (80) has a position that does not overlap vertically with the closing member (36) in the blowing channel (43). An overhanging portion (86) is formed.

    In the sixth invention, the overhang portion (86) is formed on the guide plate (80). The projecting portion (86) projects to a portion of the blowing channel (43) that does not overlap with the closing member (36) in the vertical direction (hereinafter referred to as a non-overlapping portion of the blowing channel (43)). For this reason, a part of the air in the non-overlapping portion of the blowing channel (43) is guided to the overlapping portion of the blowing channel (43) along the overhanging portion (86). As a result, the flow rate of the air in the inner flow path (73) increases in the overlapping portion of the blowout flow path (43), and condensation on the surface of the wind direction adjusting blade (53) can be prevented more reliably.

    The seventh invention is characterized in that, in the sixth invention, the overhang portion (86) is formed in a plate shape that curves toward the upstream side of the blowing channel (43).

    In the seventh aspect of the invention, since the overhang portion (86) is formed in a plate shape that curves toward the upstream side of the blowout flow path (43), it extends along the overhang portion (86) from the blowout flow path (43). Thus, air can be smoothly guided to the inner channel (73) and the outer channel (74). As a result, the flow rate of the air flowing on the front and back surfaces of the wind direction adjusting blade (53) increases, and the occurrence of condensation on these surfaces can be prevented.

    According to an eighth invention, in any one of the first to seventh inventions, the closing member is a drain pan (36).

    In the eighth invention, a part of the upstream side of the blowing channel (43) is covered with the drain pan (36).

    A ninth invention is directed to an indoor unit of an air conditioner including an indoor unit main body (21) provided on a ceiling and a decorative panel (40) provided at a lower portion of the indoor unit main body (21). The decorative panel (40) is constituted by the decorative panel of any one of the first to eighth inventions.

    In the ninth invention, the decorative panel (40) of any one of the first to eighth inventions is applied to the indoor unit (20). For this reason, in the indoor unit (20), the dew condensation of the wind direction adjusting blade (53) in the overlapping portion of the blowout flow path (43) is prevented.

    According to the present invention, the guide plate (80) is provided in the overlapping portion of the outlet flow channel (43), and the guide plate (80) guides the air to the inner flow channel (73). As a result, the flow rate of the air flowing through the inner flow path (73) can be ensured at the overlapping portion of the blowout flow path (43), and the occurrence of condensation on the surface of the wind direction adjusting blade (53) can be prevented.

    In this way, if the occurrence of condensation on the surface of the wind direction adjusting blade (53) can be prevented, it is not necessary to take measures to prevent condensation such as a heat insulating material or a flocking material on the surface of the wind direction adjusting blade (53). Since the surface of the wind direction adjusting blade (53) is easily exposed to the room, if the countermeasure against condensation is applied to this surface, the beauty of the decorative panel is also impaired. However, in the present invention, since it is not necessary to take measures against condensation on the surface of the wind direction adjusting blade (53), it is possible to sufficiently ensure the beauty of the decorative panel.

    According to the second invention, since the guide plate (80) guides air only to the inner flow path (73) in the overlapping portion of the blowout flow path (43), the flow rate of air flowing through the inner flow path (73) Can be reliably ensured, and condensation on the surface of the wind direction adjusting blade (53) can be reliably prevented.

    According to the third aspect of the invention, the flow rate of the air flowing through the inner flow path (73) can be reliably ensured even when the airflow direction adjusting blade (53) maximizes the flow rate of the air flow in the outer flow path (74). It is possible to reliably prevent the occurrence of dew condensation on the surface of the wind direction adjusting blade (53).

    According to the fourth invention, the guide plate (80) for guiding the upper air only to the inner flow path (73) can be easily realized in the non-overlapping portion of the blowing flow path (43).

    According to the fifth aspect of the invention, the air above the guide plate (80) flows downward along the curved plate portion (85). Can lead to.

    According to the sixth aspect of the invention, the air in the non-overlapping portion of the blowing channel (43) can be guided along the overhanging portion (86) to the inner channel (73) in the overlapping portion of the blowing channel (43). As a result, it is possible to further increase the air flow rate in the inner flow path (73) of the overlapping portion of the blowout flow path (43), and to more reliably prevent condensation on the surface of the wind direction adjusting blade (53).

    According to the seventh aspect of the invention, the air flow rate in the inner flow path (73) and the outer flow path (74) in the overlapping portion of the blowout flow path (43) is increased. It is possible to prevent the occurrence of condensation.

    According to the eighth aspect, since the drain pan (36) and a part of the outlet channel (43) can be arranged to overlap each other, the size of the drain pan (36) and the degree of freedom of the installation location are improved, and the decorative panel (40) Can be miniaturized.

    According to 9th invention, the indoor unit of the air conditioner which can prevent dew condensation of the wind direction adjustment blade | wing (53) in the duplication part of the blowing flow path (43) can be provided.

FIG. 1 is a schematic piping system diagram showing a configuration of a refrigerant circuit of an air conditioner according to an embodiment. FIG. 2 is a perspective view illustrating an appearance of the indoor unit according to the embodiment. FIG. 3 is a longitudinal sectional view showing the internal structure of the indoor unit according to the embodiment. FIG. 4 is a plan view of the interior of the indoor unit according to the embodiment as viewed from the top plate side. FIG. 5 is a top view of the drain pan according to the embodiment. FIG. 6 is an enlarged plan view of the guide plate. 7 is a cross-sectional view taken along line YY in FIG. 8 is a cross-sectional view taken along the line XX in FIG.

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

    An embodiment of the present invention is an air conditioner (10) that performs indoor cooling and heating. As shown in FIG. 1, the air conditioner (10) includes an outdoor unit (11) installed outdoors and an indoor unit (20) installed indoors. The outdoor unit (11) and the indoor unit (20) are connected to each other by two connecting pipes (2, 3). Thereby, a refrigerant circuit (C) is comprised in an air conditioner (10). In the refrigerant circuit (C), a vapor compression refrigeration cycle is performed by circulating the filled refrigerant.

<Configuration of refrigerant circuit>
The outdoor unit (11) is provided with a compressor (12), an outdoor heat exchanger (13), an outdoor expansion valve (14), and a four-way switching valve (15). The compressor (12) compresses the low-pressure refrigerant and discharges the compressed high-pressure refrigerant. In the compressor (12), a compression mechanism such as a scroll type or a rotary type is driven by the compressor motor (12a). The rotation speed (operation frequency) of the compressor motor (12a) is variable by an inverter device.

    The outdoor heat exchanger (13) is a fin-and-tube heat exchanger. An outdoor fan (16) is installed in the vicinity of the outdoor heat exchanger (13). In the outdoor heat exchanger (13), the air conveyed by the outdoor fan (16) and the refrigerant exchange heat. The outdoor fan (16) is constituted by a propeller fan driven by an outdoor fan motor (16a). The outdoor fan motor (16a) is configured such that its rotational speed is variable by an inverter device.

    The outdoor expansion valve (14) is an electronic expansion valve having a variable opening. The four-way switching valve (15) has first to fourth ports. In the four-way switching valve (15), the first port is connected to the discharge side of the compressor (12), the second port is connected to the suction side of the compressor (12), and the third port is the outdoor heat exchanger (13 ) And the fourth port is connected to the gas-side stop valve (5). The four-way selector valve (15) switches between a first state (state indicated by a solid line in FIG. 1) and a second state (state indicated by a broken line in FIG. 1). In the four-way selector valve (15) in the first state, the first port communicates with the third port, and the second port communicates with the fourth port. In the four-way selector valve (15) in the second state, the first port communicates with the fourth port and the second port communicates with the third port.

    The two connecting pipes are composed of a liquid connecting pipe (2) and a gas connecting pipe (3)). One end of the liquid communication pipe (2) is connected to the liquid side closing valve (4), and the other end is connected to the liquid side end of the indoor heat exchanger (32). One end of the gas communication pipe (3) is connected to the gas side shut-off valve (5), and the other end is connected to the gas side end of the indoor heat exchanger (32).

    The indoor unit (20) is provided with an indoor heat exchanger (32) and an indoor expansion valve (39). The indoor heat exchanger (32) is a fin-and-tube heat exchanger. An indoor fan (27) is installed in the vicinity of the indoor heat exchanger (32). The indoor fan (27) is a centrifugal blower driven by an indoor fan motor (27a). The indoor fan motor (27a) is configured to have a variable rotational speed by an inverter device. The indoor expansion valve (39) is connected to the liquid end side of the indoor heat exchanger (32) in the refrigerant circuit (C). The indoor expansion valve (39) is an electronic expansion valve having a variable opening.

<Detailed structure of indoor unit>
The detailed structure of the indoor unit (20) of the air conditioner (10) will be described with reference to FIGS. The indoor unit (20) of the present embodiment is configured to be embedded in the ceiling. That is, as shown in FIG. 3, the indoor unit (20) is fitted and attached to the opening (O) of the ceiling (U) facing the indoor space (R). The indoor unit (20) has an indoor unit main body (21) and a decorative panel (40) attached to the lower part of the indoor unit main body (21).

-Indoor unit body-
As shown in FIGS. 2 and 3, the indoor unit body (21) has a box-shaped casing (22) having a substantially rectangular parallelepiped shape. The casing (22) has a substantially square top plate (23) in plan view and four substantially rectangular side plates (24) extending downward from the peripheral edge of the top plate (23), and the bottom surface An opening is formed in the. As shown in FIG. 2, a vertically long box-shaped electrical component box (25) is attached to one side plate (24a) of the four side plates (24). In addition, a liquid side connection pipe (6) and a gas side connection pipe (7) connected to the indoor heat exchanger (32) pass through the side plate (24a). A liquid communication pipe (2) is connected to the liquid side connection pipe (6), and a gas communication pipe (3) is connected to the gas side connection pipe (7).

    An indoor fan (27), a bell mouth (31), an indoor heat exchanger (32), and a drain pan (36) are accommodated in the casing (22).

    As shown in FIG.3 and FIG.4, the indoor fan (27) is arrange | positioned in the inner center of the casing (22). The indoor fan (27) includes an indoor fan motor (27a), a hub (28), a shroud (29), and an impeller (30). The indoor fan motor (27a) is supported by the top plate (23) of the casing (22). The hub (28) is fixed to the lower end of the drive shaft (27b) that is rotationally driven by the indoor fan motor (27a). The hub (28) includes an annular base (28a) formed radially outward of the indoor fan motor (27a), and a central bulge (28b) bulging downward from the inner peripheral edge of the base (28a). ).

    The shroud (29) is disposed below the base (28a) so as to face the base (28a) of the hub (28). A circular central suction port (29a) communicating with the inside of the bell mouth (31) is formed in the lower portion of the shroud (29). The impeller (30) is disposed in a blade accommodating space (29b) between the hub (28) and the shroud (29). The impeller (30) is composed of a plurality of turbo blades (30a) arranged so as to be along the rotation direction of the drive shaft (27b).

    The bell mouth (31) is disposed below the indoor fan (27). The bell mouth (31) has a circular opening at the upper end and the lower end, respectively, and is formed in a cylindrical shape whose opening area increases toward the decorative panel (40). The internal space (31a) of the bell mouth (31) communicates with the blade housing space (29b) of the indoor fan (27).

    As shown in FIG. 4, the indoor heat exchanger (32) has a refrigerant pipe (heat transfer pipe) bent to surround the indoor fan (27). The indoor heat exchanger (32) is installed on the upper surface of the drain pan (36) so as to stand up. The air blown to the side from the indoor fan (27) passes through the indoor heat exchanger (32). The indoor heat exchanger (32) constitutes an evaporator that cools the air during the cooling operation, and constitutes a condenser (heat radiator) that heats the air during the heating operation.

    As shown in FIG.3 and FIG.4, the drain pan (36) is arrange | positioned under the indoor heat exchanger (32). The drain pan (36) has an inner wall part (36a), an outer wall part (36b), and a water receiving part (36c). The inner wall portion (36a) is formed along the inner peripheral edge portion of the indoor heat exchanger (32), and is configured by an annular vertical wall standing upward. The outer wall portion (36b) is formed along the four side plates (24) of the casing (22), and is configured by an annular vertical wall that stands upward. The water receiving part (36c) is formed between the inner wall part (36a) and the outer wall part (36b), and is constituted by a groove for collecting condensed water generated in the indoor heat exchanger (32). Moreover, four main body side blowing channels (37) each extending along the four side plates (24) are formed through the top and bottom of the outer wall (36b) of the drain pan (36). Each main body side blowing channel (37) communicates the space on the downstream side of the indoor heat exchanger (32) with the four panel side blowing channels (43) of the decorative panel (40).

    The indoor unit main body (21) is provided with a main body side heat insulating member (38). The main body side heat insulating member (38) is formed in a substantially box shape whose lower side is opened. The main body side heat insulating member (38) is formed along the top plate side heat insulating portion (38a) formed along the top plate (23) of the casing (22) and the side plate (24) of the casing (22). And a side plate side heat insulating portion (38b). A circular through hole (38c) through which the upper end of the indoor fan motor (27a) passes is formed at the center of the top plate heat insulating part (38a). The side plate side heat insulating part (38b) is installed in the outer part of the main body side outlet channel (37) in the outer wall part (36b) of the drain pan (36).

-Cosmetic panel-
The decorative panel (40) is attached to the lower surface of the casing (22). The decorative panel (40) includes a panel body (41) and a suction grill (60).

    The panel body (41) is formed in a rectangular frame shape in plan view. The panel body (41) is formed with one panel side suction channel (42) and four panel side outlet channels (43).

    As shown in FIG. 3, the panel side suction flow path (42) is formed in the center part of the panel main body (41). A suction port (42a) facing the indoor space (R) is formed at the lower end of the panel-side suction flow path (42). The panel-side suction channel (42) allows the suction port (42a) to communicate with the internal space (31a) of the bell mouth (31). A frame-like inner panel member (44) is fitted in the panel-side suction flow path (42). In addition, a dust collection filter (45) that captures dust in the air sucked from the suction port (42a) is provided inside the panel-side suction flow path (42).

    Each panel side blowing channel (43) is formed outside the panel side suction channel (42) so as to surround the periphery of the panel side suction channel (42). Each panel side blowing channel (43) extends along four sides of each panel side suction channel (42). Air outlets (43a) facing the indoor space (R) are formed at the lower ends of the panel-side outlet channels (43), respectively. Each panel side blowing flow path (43) makes the corresponding blower outlet (43a) and the corresponding main body side blowing flow path (37) communicate.

    As shown in FIG. 3, an inner heat insulating portion (46) is provided on the inner side of the panel side outlet channel (43) (the central portion side of the panel main body (41)). Moreover, the outer side heat insulation part (47) is provided in the outer side (outer edge part side of a panel main body (41)) of the panel side blowing flow path (43). An inner seal member (48) interposed between the panel main body (41) and the drain pan (36) is provided on the upper surfaces of the inner heat insulating portion (46) and the outer heat insulating portion (47).

    The outer panel member (49) is fitted into the inner edge of the outer heat insulating portion (47). The outer panel member (49) has an inner wall portion (50) that constitutes an inner wall surface of the main body side outlet channel (37), and a lower end portion of the inner wall portion (50) toward an outer edge portion of the panel main body (41). And an extending portion (51) extending. The extension part (51) is formed in a rectangular frame shape along the lower surface of the ceiling (U). An outer seal member (52) interposed between the extension part (51) and the ceiling (U) is provided on the upper surface of the extension part (51).

    Each body-side outlet channel (37) is provided with a wind direction adjusting blade (53) for adjusting the wind direction of the air (blowing air) flowing through the body-side outlet channel (37). The wind direction adjusting blade (53) is formed across both ends in the longitudinal direction of the main body outlet channel (37) along the side plate (24) of the casing (22). The wind direction adjusting blade (53) is configured to be rotatable about an axis of rotation (53a) extending in the longitudinal direction.

    The suction grill (60) is attached to the lower end (that is, the suction port (42a)) of the panel side suction flow path (42). The suction grill (60) includes a grill main body (61) facing the suction inlet (42a) and a rectangular extension (65 extending outward from the grill main body (61) toward each outlet (43a). ). The grill body (61) is formed in a substantially square shape in plan view. A large number of suction holes (63) are arranged in a lattice pattern in the grill body (61). These suction holes (63) are constituted by through holes that penetrate the grill body (61) in the thickness direction (vertical direction). The suction hole (63) is formed in a square shape in the opening cross section.

    The extension part (65) of the suction grill (60) is formed in a rectangular frame shape extending outward from the grill body (61) toward the outlet (43a). The extension part (65) overlaps with the panel body (41) in the vertical direction so as to overlap the lower surface of the inner heat insulating part (46). Moreover, the side edge part of the extension part (65) has shifted to the suction inlet (42a) rather than the inner edge part of the blower outlet (43a).

-Driving action-
Next, the operation of the air conditioner (10) according to this embodiment will be described. In the air conditioner (10), the cooling operation and the heating operation are switched.

<Cooling operation>
In the cooling operation, the four-way switching valve (15) shown in FIG. 1 is in a state indicated by a solid line, and the compressor (12), the indoor fan (27), and the outdoor fan (16) are in an operating state. Thereby, in the refrigerant circuit (C), a refrigeration cycle is performed in which the outdoor heat exchanger (13) serves as a condenser and the indoor heat exchanger (32) serves as an evaporator.

    Specifically, the high-pressure refrigerant compressed by the compressor (12) flows through the outdoor heat exchanger (13) and exchanges heat with outdoor air. In the outdoor heat exchanger (13), the high-pressure refrigerant dissipates heat to the outdoor air and condenses. The refrigerant condensed in the outdoor heat exchanger (13) is sent to the indoor unit (20). In the indoor unit (20), the refrigerant flows through the indoor heat exchanger (32) after being decompressed by the indoor expansion valve (39).

    In the indoor unit (20), room air flows upward in order through the suction port (42a), the panel-side suction channel (42), and the interior space (31a) of the bell mouth (31), and accommodates the blades of the indoor fan (27). It is sucked into the space (29b). The air in the blade accommodating space (29b) is conveyed by the impeller (30) and blown out radially between the hub (28) and the shroud (29). This air passes through the indoor heat exchanger (32) and exchanges heat with the refrigerant. In the indoor heat exchanger (32), the refrigerant absorbs heat from the indoor air and evaporates, and the air is cooled by the refrigerant.

    The air cooled by the indoor heat exchanger (32) is diverted to each main body side outlet passage (37), then flows downward through the panel side outlet passage (43), and passes through the outlet (43a) to the indoor space ( To R). The refrigerant evaporated in the indoor heat exchanger (32) is sucked into the compressor (12) and compressed again.

<Heating operation>
In the heating operation, the four-way switching valve (15) shown in FIG. 1 is in a state indicated by a broken line, and the compressor (12), the indoor fan (27), and the outdoor fan (16) are in an operating state. Thereby, in the refrigerant circuit (C), a refrigeration cycle is performed in which the indoor heat exchanger (32) serves as a condenser and the outdoor heat exchanger (13) serves as an evaporator.

    Specifically, the high-pressure refrigerant compressed by the compressor (12) flows through the indoor heat exchanger (32) of the indoor unit (20). In the indoor unit (20), room air flows upward in order through the suction port (42a), the panel-side suction channel (42), and the interior space (31a) of the bell mouth (31), and accommodates the blades of the indoor fan (27). It is sucked into the space (29b). The air in the blade accommodating space (29b) is conveyed by the impeller (30) and blown out radially between the hub (28) and the shroud (29). This air passes through the indoor heat exchanger (32) and exchanges heat with the refrigerant. In the indoor heat exchanger (32), the refrigerant dissipates heat to the indoor air and condenses, and the air is heated by the refrigerant.

    The air heated by the indoor heat exchanger (32) is diverted to each main body-side outlet passage (37), then flows downward through the panel-side outlet passage (43), and passes through the outlet (43a) to the indoor space ( To R). The refrigerant condensed in the indoor heat exchanger (32) is depressurized by the outdoor expansion valve (14) and then flows through the outdoor heat exchanger (13). In the outdoor heat exchanger (13), the refrigerant absorbs heat from the outdoor air and evaporates. The refrigerant evaporated in the outdoor heat exchanger (13) is sucked into the compressor (12) and compressed again.

<Guide board and surrounding structure>
Next, the guide plate (80) according to the present embodiment and the peripheral structure of the guide plate (80) will be described in detail with reference to FIGS.

    In the indoor unit (20), a part of the upstream side of the above-described panel-side blowing channel (blowing channel (43)) is covered with a drain pan (36) as a closing member. Specifically, as shown also in FIG. 5, in the indoor unit (20), the region on one end side in the longitudinal direction of the three panel side outlet channels (43) overlaps the drain pan (36) in the vertical direction. . In these panel-side outlet channels (43), a channel that does not overlap with the drain pan (36) in the vertical direction and overlaps with the main body-side outlet channel (37) constitutes the main outlet channel (71), and the drain pan (36 ) And the upper and lower flow paths constitute a sub-blowing flow path (72). And the wind direction adjustment blade | wing (53) is extended to the both ends of the longitudinal direction of the panel side blowing flow path (43) over both the main blowing flow path (71) and the sub blowing flow path (72). For example, as shown in FIG. 8, inside the panel-side outlet channel (43), the inner side (near the center of the panel body (41)) and the outer side (outside of the panel body (41)) with the wind direction adjusting blade (53) interposed therebetween. The flow paths (73, 74) are partitioned respectively. The flow path inside the wind direction adjusting blade (53) constitutes an inner flow path (73), and the flow path outside the wind direction adjusting blade (53) constitutes an outer flow path (74). Further, in the wind direction adjusting blade (53), the surface facing the inner flow path (73) forms the surface (53b) of the wind direction adjusting blade (53), and the surface facing the outer flow path (74) is the wind direction adjusting blade (53). The back surface (53c) of

    These three panel-side outlet channels (43) are each provided with a guide plate (80) between the drain pan (36) and the wind direction adjusting blade (53) in the auxiliary outlet channel (72). Since the basic configurations of these guide plates (80) are the same, one guide plate (80) of them will be described in detail below.

    As shown in FIGS. 5 and 7, the guide plate (80) includes a guide plate body (81) located in the sub-blowing flow path (72), and the main blow flow path (71) from the guide plate main body (81). And an overhanging portion (86) protruding toward the surface.

    The guide plate main body (81) is a plate-like member extending across both ends in the longitudinal direction of the sub blowing channel (72). The guide plate body (81) is formed so as to protrude from the inner wall of the outer flow path (74) (ie, the inner wall portion (50) of the outer panel member (49)) toward the center of the panel body (41). The As shown in FIG. 8, the guide plate body (81) has a substrate portion (82), a vertical plate portion (83), a horizontal plate portion (84), and a curved plate portion (85). One end of the substrate portion (82) in the width direction (left-right direction in FIG. 8) is fixed to the upper end portion of the inner wall portion (50) of the outer panel member (49). The vertical plate portion (83) is continuous with the other end portion of the substrate portion (82) and is bent downward from the other end portion. The horizontal plate (84) extends horizontally from the lower end of the vertical plate (83). The curved plate portion (85) is bent obliquely downward from the horizontal plate portion (84) toward the lower side (downstream side of the panel-side outlet channel (43)). The side end portion of the curved plate portion (85) (that is, the tip of the guide plate main body (81)) is separated from the inner wall surface (73a) facing the inner flow path (73). Thereby, in the sub blowing channel (72), a guide port (75) capable of air flow is formed between the inner wall surface (73a) of the inner channel (73) and the guide plate body (81). . The guide port (75) is connected to the inner flow path (73) facing the surface (53b) of the wind direction adjusting blade (53). In the guide plate (80), the side end portion of the curved plate portion (85) faces the inner wall surface (73a). The curved plate portion (85) is fixed to the inner wall surface (73a) of the inner flow path (73) via the two support portions (87, 87) (see FIG. 6).

    In the sub blowout flow path (72), an upper guide flow path (76) is formed between the horizontal plate portion (84) and the curved plate portion (85) of the guide plate (80) and the drain pan (36). The inflow end of the upper guide channel (76) communicates with the main outlet channel (71), and the outflow end of the upper guide channel (76) communicates with the guide port (75). That is, in the sub blowout flow path (72), the upper guide flow path (76) communicates with the inner flow path (73) via the guide port (75). That is, the guide plate (80) is configured to guide the air above the guide plate (80) only to the inner channel (73) of the inner channel (73) and the outer channel (74).

    More specifically, the guide plate (80) is positioned on the upper guide flow when the airflow direction adjusting blade (53) is positioned in a state where the air flow rate in the outer flow path (74) is maximized (the state shown in FIG. 8). The air in the path (76) is configured to be guided only to the inner flow path (73). That is, in the state shown in FIG. 8, the upstream end (53d) of the airflow direction adjusting blade (53) is close to the side end of the curved plate (85) of the guide plate (80). Therefore, even when the airflow direction adjusting blade (53) is in the state shown in FIG. 8, the guide plate (80) guides the air in the upper guide channel (76) substantially only to the inner channel (73). Will do.

    The overhang portion (86) described above is directed inward in the longitudinal direction of the panel-side outlet passage (43) from the lateral plate portion (84) of the guide plate body (81) toward the main outlet passage (71). It protrudes. Thereby, the overhang | projection part (86) has faced the main body side blowing flow path (37). As shown in FIG. 7, the projecting portion (86) is formed in a plate shape that curves from the guide plate body (81) toward the upstream side of the panel-side outlet channel (43). As a result, compared with the case where the overhang portion (86) is formed in a horizontal plate shape, the air flow in the main blowing channel (71) is more easily guided to the sub blowing channel (72).

-Action of guide plate-
In the panel side outlet channel (43) of the indoor unit (20) of the embodiment, the outer channel (74) has a higher air flow rate than the inner channel (73). In the indoor unit (20), it is necessary to blow out air from the air outlet (43a) to the outside (horizontal) from the vertical direction. This is because the amount of air flowing on the side) is relatively large.

    On the other hand, if the position and shape of the wind direction adjusting vane (53) and the panel side outlet channel (43) are set so as to increase the flow rate of the outer channel (74) in this way, the auxiliary outlet covered with the drain pan (36) In the flow path (72), the flow rate of the inner flow path (73) becomes extremely small. When the air hardly flows through the inner flow path (73) of the sub-blowing flow path (72), warm air in the room flows into the inner flow path (73) of the sub-blowing flow path (72) through the blow-out opening (43a). It becomes easy to do. As a result, in the sub-blowing flow path (72) having the conventional configuration, the warm air flowing into the inner flow path (73) is cooled by the surface (53b) of the airflow direction adjusting blade (53), and the condensed water May occur. Therefore, in the present embodiment, the guide plate (80) is provided in order to prevent the generation of such condensed water. As a result, in the sub-blowing flow path (72), the flow rate of air flowing through the inner flow path (73) is increased, and the generation of condensed water on the surface (53b) of the wind direction adjusting blade (53) can be prevented.

    Specifically, the air that has passed through the indoor heat exchanger (32) flows through the main body outlet flow passage (37) as described above. On the other hand, in the panel side blowing channel (43), the upper end surface of the sub blowing channel (72) is covered with the drain pan (36). For this reason, the air in the main body outlet channel (37) flows into the main outlet channel (71). The air in the main outlet channel (71) is divided into the inner channel (73) and the outer channel (74), and is supplied into the room from the outlet (43a). Moreover, a part of air of the main blowing flow path (71) flows into the sub blowing flow path (72) along the upper surface and the lower surface of the projecting portion (86) of the guide plate (80). The air flowing through the upper guide channel (76) on the upper side of the guide plate (80) is guided along the horizontal plate portion (84) and the curved plate portion (85) of the guide plate (80) shown in FIG. Sent to (75). This air flows through the inner flow path (73) of the sub blow-out flow path (72), and is supplied to the room through the blow-out opening (43a).

    Thus, in the present embodiment, the air flowing through the upper guide channel (76) of the sub-blowing channel (72) is substantially guided only to the inner channel (73). That is, the guide plate (80) guides the air so that the air to be guided flows through the inner flow path (73) more than the outer flow path (74). As a result, the air flow rate can be secured to some extent, and the generation of condensed water on the surface (53b) of the wind direction adjusting blade (53) can be prevented.

    Further, most of the air sent from the main blowing channel (71) to the lower side of the guide plate (80) is introduced into the outer channel (74). For this reason, in the sub blowout flow path (72), the flow rate of the air flowing through the outer flow path (74) does not become insufficient. Accordingly, no dew condensation occurs on the back surface (53c) of the airflow direction adjusting blade (53) in the sub blowout flow path (72).

-Effect of the embodiment-
According to the above-described embodiment, the guide plate (80) is provided in the sub-blowing flow path (72) covered by the drain pan (36), and the air above the guide plate (80) is substantially only in the inner flow path (73). To guide you to. As a result, in the sub-blowing flow path (72), the flow rate of the air flowing through the inner flow path (73) can be secured, and the occurrence of condensation on the surface of the wind direction adjusting blade (53) can be prevented.

    If condensation on the surface (53b) of the wind direction adjusting blade (53) can be prevented in this way, it is not necessary to take measures to prevent condensation on the surface (53b) such as a heat insulating material or a flocking material. Since the surface (53b) of the wind direction adjusting blade (53) is a surface exposed to the indoor space (R), particularly at the closed position of the air outlet (43a), if this surface (53b) is subjected to dew condensation countermeasures, The aesthetics of the panel (40) will be damaged. However, in this embodiment, since it is not necessary to take measures against condensation on the surface (53b) of the wind direction adjusting blade (53), it is possible to sufficiently ensure the beauty of the decorative panel (40). Note that the back surface (53c) of the wind direction adjusting blade (53) is a surface that is hardly exposed to the indoor space (R). Therefore, a dew condensation prevention part (a means for preventing the occurrence of dew condensation on the back surface (53c)) such as a heat insulating material or a flocking material may be provided on the back surface (53c) of the wind direction adjusting blade (53).

    Further, according to the above embodiment, as shown in FIG. 8, the wind direction adjusting blade (53) maximizes the air flow rate in the outer flow path (74) (that is, the wind direction adjusting blade (53) is the most horizontal). In the inclined state), the guide plate (80) guides air only to the inner flow path (73). In other words, the inner side end of the guide plate (80) is located closer to the center of the panel body (41) than the upstream end (53d) of the airflow direction adjusting blade (53) in the state shown in FIG. ing. For this reason, as shown in FIG. 8, the air flow rate in the inner flow path (73) of the sub-blowing flow path (72) even during operation in which the air flow rate in the outer flow path (74) becomes relatively large. Can be ensured. As a result, in the indoor unit (20), it is possible to prevent dew condensation from occurring on the surface (53b) of the wind direction adjusting blade (53) in the sub-blowing flow path (72) while ensuring a horizontal blowing flow rate. .

    Further, according to the above embodiment, since the curved plate portion (85) bent toward the air downstream side is formed at the tip portion of the guide plate body (81), the airflow resistance can be reduced, and the air in the upper guide channel (76) can be reduced. Can be smoothly and reliably supplied to the inner flow path (73). Moreover, since the front-end | tip part of a guide-plate main body (81) has faced the inner wall face (73a) which faces an inner flow path (73), the air of an upper guide flow path (76) moves to the outer flow path (74) side. The air can be prevented from being guided, and the air can be reliably guided to the inner flow path (73).

    Further, according to the embodiment, since the overhanging portion (86) facing the main blowing channel (71) is formed in the guide plate (80), a part of the air in the main blowing channel (71) is surely sub-charged. It can guide to the blowing channel (72). As a result, the flow rate of the air flowing through the inner flow path (73) and the outer flow path (74) of the sub-blowing flow path (72) increases, and the air flow direction blades (53) on the front surface (53b) and back surface (53c) Generation of condensed water can be reliably prevented. Furthermore, since the overhang portion (86) is formed in a plate shape curved toward the upstream side of the air, the air in the main blowing channel (71) is easily attracted to the sub blowing channel (72).

<< Other Embodiments >>
In the said embodiment, the obstruction | occlusion member which covers a part of upstream of the blowing flow path (43) is comprised by the drain pan (36). However, the closing member may be, for example, a heat insulating member bulged so as to cover a part of the upstream side of the blowing channel (43) or other members.

    Further, the guide plate (80) of the above embodiment is configured to guide the air in the upper guide channel (76) substantially only to the inner channel (73) in the sub-blowing channel (72). However, it may be configured to guide part of the air to the outer flow path (74). In this case, the guide plate (80) has a flow rate of air in the inner flow path (73) out of air guided from the upper guide flow path (76) to both the inner flow path (73) and the outer flow path (74). However, the air is guided so as to be larger than the flow rate of the air in the outer flow path (74).

    Moreover, in the said embodiment, the indoor unit (20) of the air conditioner (1) was comprised by the ceiling embedding type fitted in the opening part (O) of a ceiling (U). However, the indoor unit (20) may be configured to be suspended from the ceiling and suspended from the ceiling disposed in the indoor space (R). The ceiling-suspended indoor unit (20) includes a bowl-shaped casing having a top plate, four side plates, and a bottom plate, and the bottom plate is configured in the decorative panel (40) according to the present invention. Good. In this case, the top plate and the four side plates are provided in the indoor unit body (21). That is, the decorative panel (40) is provided in the lower part of the indoor unit body (21).

    INDUSTRIAL APPLICABILITY As described above, the present invention is useful as a measure for preventing dew condensation on the airflow direction adjusting blades arranged in the blowout flow path in the air conditioner decorative panel and the indoor unit of the air conditioner including the decorative panel. It is.

10 Air conditioner
20 Indoor unit
21 Indoor unit body
36 Drain pan (blocking member)
41 Panel body
43 Panel side outlet (outlet passage)
53 Wind adjustment blade
80 Information board
85 Curved plate
86 Overhang
73 Internal flow path
73a Inner wall
74 Outer channel

Claims (9)

A decorative panel for an air conditioner provided at a lower portion of an indoor unit body (21) provided on a ceiling,
A panel body (41) in which a blowout flow path (43) is formed and a part of the upstream side of the blowout flow path (43) is covered by a closing member (36);
A wind direction adjusting blade (53) for partitioning the blowing channel (43) into an inner channel (73) near the center of the panel body (41) and an outer channel (74) near the outside of the panel body (41);
A guide plate (80) disposed between the closing member (36) and the wind direction adjusting blade (53) in the blowing channel (43) and configured to guide air to the inner channel (73); A decorative panel for an air conditioner, characterized by comprising: In claim 1,
The decorative panel for an air conditioner, wherein the guide plate (80) is configured to guide air only to the inner flow path (73). In claim 2,
The guide plate (80) guides air only to the inner flow path (73) when the wind direction adjusting blade (53) is in a state where the flow rate of air in the outer flow path (74) is maximized. A decorative panel for an air conditioner characterized in that it is configured. In any one of Claims 1 thru | or 3,
The guide plate (80) protrudes from the inner wall (50) of the outer flow path (74) toward the center side of the panel body (41), and the tip thereof is connected to the inner wall surface (73a) of the inner flow path (73). An air conditioner decorative panel characterized by being spaced apart. In claim 4,
A decorative panel for an air conditioner, characterized in that a curved plate portion (85) bent toward the downstream side of the blowing channel (43) is formed at a tip portion of the guide plate (80). In any one of Claims 1 thru | or 5,
The guide plate (80) is formed with an overhanging portion (86) that protrudes to a position that does not overlap with the closing member (36) in the blowing channel (43). Harmonic makeup panel. In claim 6,
The overhanging part (86) is formed in a plate shape that curves toward the upstream side of the blowing channel (43). In any one of Claims 1 thru | or 7,
The decorative panel for an air conditioner, wherein the closing member is a drain pan (36). An indoor unit of an air conditioner including an indoor unit body (21) provided on a ceiling and a decorative panel (40) provided at a lower portion of the indoor unit body (21),
The said decorative panel (40) is comprised by the decorative panel of any one of Claims 1 thru | or 8. The indoor unit of the air conditioner characterized by the above-mentioned.

Images