JP4433080B2 - Indoor unit of air conditioner - Google Patents

Description

    The present invention relates to an indoor unit of an air conditioner, and particularly relates to processing of dust removed from an air filter.

    2. Description of the Related Art Conventionally, in an indoor unit of an air conditioner equipped with an air filter at an air suction port, a unit provided with dust removing means for removing dust trapped by the air filter is known.

For example, the air conditioning apparatus of Patent Document 1 includes a cleaning unit as dust removing means. The cleaning unit includes a cleaning brush, a recovery brush, and a dust box. The cleaning brush moves while contacting the surface of the air filter to remove dust. The collection brush scrapes off dust adhering to the cleaning brush. The dust box stores the cleaning brush and the recovery brush, and stores dust scraped by the recovery brush. The dust stored in the dust box is recovered by opening the front panel of the casing body and sucking it with a vacuum cleaner from the opening formed in the box body.
JP 2007-107764 A

    Incidentally, since the dust box of Patent Document 1 described above is disposed in the vicinity of the air filter (30) (that is, in the vicinity of the intake air passage), it is necessary to reduce the volume as much as possible so as not to obstruct the air flow. is there. Furthermore, the dust box cannot capture a large dust storage volume as much as a cleaning brush or the like is accommodated. Therefore, there has been a problem that the amount of stored dust cannot be earned. Furthermore, the arrangement of the dust box is also strictly limited. As a result, the dust in the dust box has to be collected frequently, and the collecting operation has become complicated due to the influence of the arrangement.

    The present invention has been made in view of the above points, and the object thereof is to be removed in an indoor unit of an air conditioner having a function of removing dust from an air filter without much trouble of a user. It is to treat dust effectively.

According to a first aspect of the present invention, an indoor heat exchanger (22), an indoor fan (21) for sucking air from the room, and an air filter (30) provided on the suction side of the indoor fan (21) are provided in the casing (10). ) And dust removing means (50) for removing dust trapped by the air filter (30). The indoor unit of the present invention includes a dust container (60) that is provided in the casing (10) and stores dust removed by the dust removing means (50), and the dust container (60). volume is larger, the dust collecting box which is connected dust storage container (60) by the transfer duct (81) and (90), provided in the casing (10) in Rutotomoni the dust collection box ( 90) and a transport fan (82) for transporting dust stored in the dust storage container (60) to the dust collection box (90) through the transport duct (81) by suction , and To communicate with the dust collection box (90) through the suction duct (84), and suck the dust conveyed to the dust collection box (90) from the outside through the suction duct (84) by a vacuum cleaner. in which and a cleaner insertion port (85) Further, the transfer fan (82) is connected to the side of the dust collection box (90) opposite to the connection side of the transfer duct (81), and the dust collection box (90) A filter (91) is provided at the connection portion of the transfer fan (82).

    In the above invention, when the air sucked into the casing (10) by the indoor fan (21) passes through the air filter (30), dust contained in the air is captured by the air filter (30). The dust captured by the air filter (30) is removed by the dust removing means (50) and stored in the dust container (60). The dust in the dust container (60) is transported together with air to a predetermined position (for example, a relatively large space inside the casing (10) or outside the casing (10)) by the transport fan (82). That is, in the present invention, the dust removed from the air filter (30) is once stored in the dust storage container (60), but is then transported to another arbitrary place without bothering the user.

Further, in the above invention, the air in the dust collection box (90) is sucked into the transfer fan (82). Accordingly, the dust in the dust container (60) is transferred to the dust collection box (90) through the transfer duct (81). Since the dust collection box (90) has a large volume, a large amount of dust can be collected.

Furthermore, in the above invention, the dust that has been transferred to the dust collection box (90) is inserted through the suction duct (84) by the user inserting the hose of the vacuum cleaner into the cleaner insertion port (85). It is collected by suction with a vacuum cleaner. Furthermore, depending on the suction power of the vacuum cleaner, the dust stored in the dust storage container (60) is also transferred to the vacuum cleaner via the transport duct (81), the dust collection box (90), and the suction duct (84) in this order. To be recovered.

According to a second aspect of the invention, an indoor heat exchanger (22), an indoor fan (21) for sucking air from the room, and an air filter (30) provided on the suction side of the indoor fan (21) are provided in the casing (10). ) And dust removing means (50) for removing dust trapped by the air filter (30). The indoor unit of the present invention includes a dust container (60) that is provided in the casing (10) and stores dust removed by the dust removing means (50), and the dust container (60). A dust collection box (90) having a large volume and connected by the dust storage container (60) and the transfer duct (81), and provided in the casing (10) and the dust storage container (60) And a transport fan (82) for transporting dust stored in the dust storage container (60) to the dust collection box (90) through the transport duct (81) by air blowing, and the dust trap Cleaning for communicating with the collection box (90) via the suction duct (84) and sucking the dust conveyed to the dust collection box (90) from the outside through the suction duct (84) by a vacuum cleaner With a machine insertion slot (85) . Further, the transfer fan (82) is connected to a side of the dust container (60) opposite to the connection side of the transfer duct (81).

In the above invention, when the air sucked into the casing (10) by the indoor fan (21) passes through the air filter (30), dust contained in the air is captured by the air filter (30). The dust captured by the air filter (30) is removed by the dust removing means (50) and stored in the dust container (60). The dust in the dust container (60) is transported together with air to a predetermined position (for example, a relatively large space inside the casing (10) or outside the casing (10)) by the transport fan (82). That is, in the present invention, the dust removed from the air filter (30) is once stored in the dust storage container (60), but is then transported to another arbitrary place without bothering the user.

Further, in the above invention, the air blown by the transfer fan (82) is sent to the dust container (60). By this air blowing action, the dust in the dust container (60) is transferred to the dust collecting box (90) through the transfer duct (81) and stored. Since the dust collection box (90) has a large volume, a large amount of dust can be collected.

Furthermore, in the above invention, the dust that has been transferred to the dust collection box (90) is inserted through the suction duct (84) by the user inserting the hose of the vacuum cleaner into the cleaner insertion port (85). It is collected by suction with a vacuum cleaner. Furthermore, depending on the suction power of the vacuum cleaner, the dust stored in the dust storage container (60) is also transferred to the vacuum cleaner via the transport duct (81), the dust collection box (90), and the suction duct (84) in this order. Collected.

According to a third invention, in the first or second invention, the dust removing means (50) is provided in the dust container (60) and is in contact with the air filter (30). And a moving means (40) for moving the air filter (30) relative to the brush member (51).

    In the above invention, the air filter (30) moves while being in contact with the brush member (51) by the moving means (40). Along with this movement, dust on the air filter (30) is scraped off (removed) by the brush member (51). The dust removed by the brush member (51) is stored in the dust container (60) as it is.

In a fourth aspect based on the third aspect , the brush member (51) of the dust removing means (50) includes a brush (51b) made of a pile fabric and contacting the air filter (30). Is.

    In the above invention, the air filter (30) moves while being in contact with the brush (51b) of the brush member (51). Along with this movement, dust on the air filter (30) is scraped off (removed) by the brush (51b). On the other hand, since the brush (51b) is made of a pile fabric, the length of the hairs is relatively short. Therefore, in the dust container (60), the air flow by the transfer fan (82) is not so hindered by the bristles of the brush (51b). That is, the flow resistance of air in the dust container (60) is reduced.

According to a fifth invention, in the first or second invention, provided in the dust container (60), the transfer duct (81) or the dust collection box (90), the flow rate of air is detected. A flow velocity detecting means (69) is provided.

    In the above invention, the flow velocity of the air in the dust container (60), the transfer duct (81) or the dust collection box (90) (that is, the wind velocity) is detected by the flow velocity detection means (69). In the present invention, the dust in the dust collection box (90) is full when the air velocity by the flow velocity detection means (69) becomes a predetermined value or less during suction by the conveying fan (82) or during blowing. Determined. Alternatively, it is determined that the transport duct (81) is clogged with dust or the like. In other words, when the amount of dust stored in the dust collection box (90) is small, or when there is no clogging in the transfer duct (81), the wind speed by the flow velocity detection means (69) increases, and the dust collection box (90) As the amount of stored dust increases, and when the transport duct (81) becomes clogged, the wind speed by the flow velocity detecting means (69) decreases. As described above, the present invention detects a change (increase) in air flow resistance from the air flow velocity, and detects a full state of dust in the dust collection box (90), clogging in the transport duct (81), and the like. I tried to do it.

In a sixth aspect based on the fifth aspect , the flow velocity detecting means (69) is provided on the upstream side of the dust reservoir of the dust reservoir (60).

    In the above invention, the air flow velocity upstream of the dust reservoir is detected by the flow velocity detection means (69). That is, as compared with the case where the flow velocity detection means (69) is provided on the downstream side of the dust reservoir, the flow velocity of the air in which dust is not mixed is detected.

As described above, according to the first or second invention, the dust removed from the air filter (30) and stored in the dust container (60) is transported to a predetermined position by the transport fan (82). I made it. Therefore, it is possible to easily move the dust to a relatively large place (for example, the back of the ceiling) and further to a predetermined place where the disposal work is easy without bothering the user. Here, since the dust container (60) is disposed in the vicinity of the air filter (30), that is, in the vicinity of the intake air passage, it is necessary to reduce the volume as much as possible so as not to obstruct the air flow. Then, a large amount of dust cannot be stored in the dust container (60), but in the present invention, a large amount of dust can be stored in a place different from the dust container (60). Therefore, it is possible to reduce the trouble of the dust processing by the user.

Further, according to the first or second invention, the dust is transferred from the dust container (60) to the dust collecting box (90) having a larger volume by the suction action or the air blowing action of the transfer fan (82). It was transported and stored. By disposing the dust collection box (90) at a place where disposal is easy, a large amount of dust can be reliably collected and the efficiency of dust disposal can be improved. Further, if a common dust collection box (90) is provided for a plurality of indoor units, the dust captured by each indoor unit can be collected together. Therefore, even when a plurality of indoor units are provided, dust processing efficiency can be improved.

According to the first or second invention, the dust in the dust collection box (90) and the dust container (60) is sucked only by inserting the hose of the cleaner into the cleaner insertion port (85). be able to. Therefore, dust can be easily processed, and the trouble of dust processing can be further reduced.

Further, according to the third aspect of the invention, the dust removed by the brush member (51) can be surely once accumulated in the dust container (60). Since the air filter (30) is moved relative to the brush member (51), dust can be removed over the entire surface of the air filter (30). In this configuration, the volume and arrangement of the dust container (60) are further limited, but the present invention can easily move the dust from the dust container (60) to a wider place. A large amount of dust can be effectively stored.

According to the fourth aspect of the invention, the brush member (51) is provided with the brush (51b) made of a pile fabric, so that the bristle of the brush (51b) is shortened. Therefore, the air flow resistance in the dust container (60) can be reduced. As a result, it is possible to improve the transfer efficiency of the dust stored in the dust storage container (60).

According to the fifth aspect of the invention, the air flow rate detecting means (69) is provided in the dust container (60), the transfer duct (81) or the dust collection box (90). As a result, it is possible to detect an increase or decrease in air flow resistance in the dust container (60), the transfer duct (81), or the dust collection box (90). Based on the increase / decrease in the air flow resistance, it is possible to detect a full state of dust in the dust collection box (90) (that is, the degree of dust filling) and clogging in the transfer duct (81). . As a result, it is possible to properly collect (discharge) dust from the dust collection box (90) to the outside of the indoor unit, and to detect clogging due to dust etc. in the transport duct (81) at an early stage. Can do. Therefore, the reliability of the indoor unit can be increased.

Furthermore, according to the sixth invention, the flow velocity detecting means (69) is provided on the upstream side of the dust reservoir. Therefore, it is possible to detect the air flow velocity in a place where there is no dust. Thereby, since the sensing of the flow velocity detection means (69) is not affected by dust, the accuracy of detecting the wind speed is increased. As a result, the timing for collecting (discharging) the dust from the dust collection box (90) to the outside of the indoor unit can be more appropriately achieved. Furthermore, it is possible to suppress the deterioration of the flow velocity detection means (69) due to dust. As described above, the reliability of the indoor unit can be further improved.

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

    The indoor unit (1) of the present embodiment constitutes a part of the air conditioner and is installed on the ceiling of the indoor space. The air conditioner includes a refrigerant circuit in which a compressor, an outdoor heat exchanger and an expansion valve provided in an outdoor unit, and an indoor heat exchanger (22) provided in the indoor unit (1) are connected by piping. Yes. The refrigerant circuit performs a vapor compression refrigeration cycle by reversibly circulating the refrigerant. In the air conditioner, a cooling operation in which the indoor heat exchanger (22) functions as an evaporator in the refrigerant circuit and a heating operation in which the indoor heat exchanger (22) functions as a condenser in the refrigerant circuit are performed.

<Configuration of indoor unit>
As shown in FIGS. 1 and 2, the indoor unit (1) includes a casing (10) and a decorative panel (11). Inside the casing (10) are an indoor heat exchanger (22), a drain pan (23), an indoor fan (21), an air filter (30), a filter driving means (40), a dust removing means (50), a dust container (60) A dust transfer means (80) and a dust collection box (90) are provided.

    The casing (10) is formed in a substantially rectangular parallelepiped box shape whose lower side is open. A heat insulating material (17) is laminated on the inner surface of the casing (10). The casing (10) is installed in a state where the lower part is inserted through the opening of the ceiling board.

    The decorative panel (11) is formed in a rectangular plate shape. The plan view shape of the decorative panel (11) is slightly larger than the plan view shape of the casing (10). The decorative panel (11) is attached so as to cover the lower side of the casing (10) with the seal member (16) interposed therebetween. In a state where the decorative panel (11) is attached to the casing (10), the decorative panel (11) is exposed indoors.

    The decorative panel (11) is formed with one inlet (13) and four outlets (14). The suction port (13) is formed in a rectangular shape, and is formed in the central portion of the decorative panel (11). A suction grill (12) formed in a slit shape is fitted into the suction port (13). Each air outlet (14) is formed in an elongated rectangular shape. Each blower outlet (14) is formed along each side of the decorative panel (11). Each air outlet (14) is provided with a wind direction adjusting plate (15). The wind direction adjusting plate (15) is rotated to adjust the wind direction (the blowing direction).

    The indoor fan (21) is a so-called turbo fan. The indoor fan (21) is disposed near the center of the casing (10) and is located above the suction port (13). The indoor fan (21) includes a fan motor (21a) and an impeller (21b). The fan motor (21a) is fixed to the top plate of the casing (10). The impeller (21b) is connected to the rotation shaft of the fan motor (21a). A bell mouth (24) communicating with the suction port (13) is provided below the indoor fan (21). In the casing (10), the bell mouth (24) divides the space upstream of the indoor heat exchanger (22) into an indoor fan (21) side and a suction grill (12) side. The indoor fan (21) is configured to blow out air sucked from below through the bell mouth (24) in the circumferential direction.

    The indoor heat exchanger (22) is a cross fin type fin-and-tube heat exchanger. The indoor heat exchanger (22) is formed in a square shape in a plan view, and is disposed so as to surround the indoor fan (21). In the indoor heat exchanger (22), heat is exchanged between the refrigerant and indoor air (blowout air) sent by the indoor fan (21).

    The drain pan (23) is provided below the indoor heat exchanger (22). The drain pan (23) is for receiving drain water generated by condensation of moisture in the air in the indoor heat exchanger (22). The drain pan (23) is provided with a drain pump for draining drain water (not shown). The drain pan (23) is sloped so that drain water collects at the location where the drain pump is installed.

    A partition plate (25) is provided below the bell mouth (24). The partition plate (25) partitions the space between the bell mouth (24) and the suction grille (12) vertically. That is, the partition plate (25) divides the upstream space of the indoor heat exchanger (22) into the indoor heat exchanger (22) side including the bell mouth (24) and the suction grille (12) side.

    A vent hole (26) is formed in the center of the partition plate (25) for allowing air sucked from the suction port (13) to flow into the bell mouth (24). As shown in FIG. 3, the vent hole (26) is partitioned into a fan shape by four radial members (27) in which the circular hole extends in the radial direction. The radial members (27) are connected to each other at the center of the circle, and a cylindrical filter rotation shaft (28) protrudes downward at that portion. The filter rotation shaft (28) is a rotation shaft for rotating the air filter (30). One radial member (27) is provided with two filter holders (29).

    As shown in FIG. 3, the air filter (30) is disposed below the partition plate (25) and is formed in a disk shape having a size covering the inlet of the bell mouth (24). Specifically, the air filter (30) includes an annular filter body (31) and a mesh member (37). A gear portion (32) is provided on the outer peripheral surface of the filter body (31). A cylindrical shaft insertion portion (33) supported by six radial ribs (34) is provided at the annular central portion of the filter body (31). That is, each radial rib (34) extends radially from the shaft insertion portion (33). In addition, an inner circumferential rib (35) and an outer circumferential rib (36) formed in an annular shape concentric with the filter body (31) are provided on the inner circle portion of the filter body (31). The outer circumferential rib (36) has a larger diameter than the inner circumferential rib (35). The mesh member (37) is stretched over the entire inner circle of the filter body (31). The air sucked from the suction port (13) passes through the mesh member (37) of the air filter (30) and flows into the bell mouth (24). At that time, dust in the air is captured by the mesh member (37).

    The air filter (30) is urged downward by the filter retainer (29) described above coming into contact with the circumferential ribs (35, 36). Thus, the air filter (30) is pressed against the rotating brush (51) of the dust removing means (50) described later. Therefore, the removal efficiency by the dust removing means (50) is improved.

    As shown in FIG. 4, the air filter (30) is attached by inserting the shaft insertion portion (33) into the filter rotation shaft (28) of the partition plate (25). The air filter (30) is rotatable about the filter rotation shaft (28). The dust container (60) is disposed below the air filter (30). Then, with the air filter (30) fitted in the shaft insertion portion (33), the filter mounting portion (68) of the dust container (60) is stopped by the shaft insertion portion (33) of the partition plate (25). It is fixed by a screw (28a). Thereby, an air filter (30) is hold | maintained between a partition plate (25) and a dust storage container (60).

    In the vicinity of the air filter (30), filter driving means (40) for rotationally driving the air filter (30) is provided (see FIG. 2). That is, the filter driving means (40) constitutes a moving means for moving the air filter (30) relative to the rotating brush (51).

    Specifically, as shown in FIG. 5, the filter drive means (40) includes a filter drive motor (41) and a limit switch (44). A drive gear (42) is provided on the drive shaft of the filter drive motor (41), and the drive gear (42) meshes with the gear portion (32) of the filter body (31). On one end surface of the drive gear (42), a switch operating portion (43) that is a projecting piece is provided. The switch operating portion (43) acts on the lever (44a) of the limit switch (44) by the rotation of the drive gear (42). When the switch operating portion (43) acts on the lever (44a), the limit switch (44) detects. That is, the switch operating part (43) and the limit switch (44) are for detecting the rotational position of the drive gear (42).

    Next, the dust removal means (50), the dust container (60) and the dust transfer means (80) will be described with reference to FIGS. These dust removing means (50) and the like are disposed below the partition plate (25) and the air filter (30) (see FIGS. 1 and 2).

    The dust removing means (50) is for removing dust trapped by the air filter (30). The dust removing means (50) includes a rotating brush (51), a cleaning brush (52), and a brush driving means (53). The rotating brush (51) constitutes a brush member according to the present invention.

    As shown in FIG. 7, the rotating brush (51) and the cleaning brush (52) are provided in a brush opening (63) of a dust container (60) described later.

    The rotating brush (51) includes an elongated cylindrical shaft (51a) and a brush (51b) provided on the outer peripheral surface of the shaft (51a). The brush (51b) is composed of a plurality of flocks. The brush (51b) is provided in a part of the shaft (51a) in the circumferential direction, and is provided over the length direction of the shaft (51a). The cleaning brush (52) is disposed on the rear side of the rotating brush (51).

    The cleaning brush (52) includes a main body portion (52a), a brush (52b), and a spring portion (52c). The main body (52a) is a plate-like member and is formed to have the same length as the shaft (51a) of the rotating brush (51). The main body (52a) has a plate surface facing the outer peripheral surface of the rotating brush (51). Moreover, the upper part of a main-body part (52a) becomes the circular arc part corresponding to the outer peripheral surface of the shaft (51a) of a rotating brush (51). A brush (52b) is provided on the arc portion of the main body (52a) along the length direction of the main body (52a). The spring part (52c) is provided at the lower end of the main body part (52a) and is attached to the inner wall of the dust container (60). That is, the main body (52a) is supported by the spring (52c).

    The rotating brush (51) and the cleaning brush (52) are formed to have a length equal to or greater than the radius of the air filter (30). The rotating brush (51) and the cleaning brush (52) are disposed so as to extend radially outward from the center of the air filter (30).

    The rotating brush (51) is configured to remove dust from the mesh member (37) when the brush (51b) contacts the mesh member (37) of the rotating air filter (30). The rotating brush (51) is reversibly rotated by the brush driving means (53). As shown in FIG. 6, the brush drive means (53) includes a brush drive motor (54), a drive gear (55) and a driven gear (56) meshing with each other. The drive gear (55) is provided on the drive shaft of the brush drive motor (54), and the driven gear (56) is provided on the end of the shaft (51a) of the rotating brush (51). With this configuration, the rotating brush (51) is driven to rotate.

    The brush (52b) of the cleaning brush (52) is configured to come into contact with the brush (51b) of the rotating brush (51) when the rotating brush (51) is rotated by the brush driving means (53). By the contact, dust is removed from the brush (51b) of the rotating brush (51). That is, the cleaning brush (52) removes dust from the rotating brush (51) and cleans the rotating brush (51). The dust removing action of the rotating brush (51) and the cleaning brush (52) will be described in detail later.

    The brushes (51b, 52b) of the rotating brush (51) and the cleaning brush (52) are made of a so-called pile fabric. This pile fabric is a hair fiber in which hair (pile yarn) is woven into a base fabric, and has a relatively short hair. The pile fabric is an inclined pile in which the fur is inclined in a certain direction.

    Specifically, the bristles of the brush (51b) in the rotating brush (51) are inclined from the shaft (51a) toward the left side in FIG. That is, the bristles of the brush (51b) are inclined so as to face the rotation direction of the air filter (30). Thus, when the air filter (30) rotates so as to face the fur of the brush (51b), the dust on the mesh member (37) is scraped out efficiently. On the other hand, when the air filter (30) rotates in the inclined direction with respect to the bristles of the brush (51b), the dust on the mesh member (37) is not scraped, and conversely, the dust trapped on the brush (51b) Removed. Further, the bristles of the brush (52b) in the cleaning brush (52) are inclined downward from the main body (52a) in FIG. That is, the bristles of the brush (52b) are inclined so as to face the rotational direction when the rotating brush (51) rotates clockwise in FIG.

    The dust container (60) stores dust removed from the rotating brush (51) by the cleaning brush (52). As shown in FIG. 7, the dust container (60) is a columnar container whose side view shape (viewed from the right side in FIG. 6) is bent in a slightly inverted shape. In the dust container (60), the upper part is a removal part (61) from which dust of the air filter (30) is removed, and the lower part is a storage part in which dust removed from the air filter (30) is stored. (62).

    A brush opening (63) extending in the longitudinal direction is formed in the upper plate of the removal portion (61), and the rotating brush (51) and the cleaning brush (52) are formed in the brush opening (63) as described above. ) Is provided. In addition, the filter attachment part (68) mentioned above is provided in one side of the removal part (61). Further, the edge (61a) on the rear side of the brush opening (63) (that is, the side opposite to the cleaning brush (52) side) has a tapered shape that gradually decreases toward the rotating brush (51). Is formed in an arc shape along the brush (51b) of the rotating brush (51). Thereby, the clearance gap between an edge part (6c) and a rotating brush (51) becomes small infinitely. Therefore, the dust of the air filter (30) that has passed through the rotating brush (51) without being removed by the rotating brush (51) immediately passes along the edge (61a) of the air filter (30). Guided in the direction of travel. That is, the dust that has passed through the rotating brush (51) moves smoothly while being attached to the air filter (30) without being blocked by the upper plate of the removing portion (61). By devising the edge portion (61a) in this way, it is possible to prevent dust from stagnation in the gap between the rotating brush (51) and the upper plate of the removal portion (61). When the stagnation occurs, the dust gradually grows and becomes a large lump, and eventually is ejected from the gap and falls into the room or the like, but this embodiment prevents this. Furthermore, since the gap between the edge (61a) and the rotating brush (51) is reduced, the sealing property (sealability) of the dust container (60) is increased.

    As for the said storage part (62), the lower end side (bottom part side) has expanded in circular arc shape. And the dust removed from the rotating brush (51) by the cleaning brush (52) falls and is stored in the arc portion of the storing portion (62). One end of the storage part (62) (that is, the side on which the brush drive means (53) is provided) is a mesh part (66) in which a plurality of minute holes are formed. The other end of the reservoir (62) (that is, the side on which the filter mounting portion (68) is provided) is connected to a transfer port (to which a transfer duct (81) of a dust transfer means (80) described later is connected ( 67).

    As shown in FIG. 8, the dust container (60) is provided with a storage amount detection means (70) for detecting the amount of dust in the storage portion (62). The storage amount detection means (70) includes a sensor box (71). The sensor box (71) is provided near the second end (67) of the storage part (62) of the dust container (60) (see FIG. 6). The sensor box (71) is formed so as to extend in the transverse direction of the reservoir (62) and cover the bottom thereof. A light emitting LED (72) and a phototransistor (73) are housed in the sensor box (71). The light emitting LED (72) and the phototransistor (73) are arranged so as to face each other with the reservoir (62) sandwiched in the transverse direction. On the other hand, a first transparent window (64) and a second transparent window (65) are provided on the wall of the reservoir (62) at portions corresponding to the light emitting LED (72) and the phototransistor (73).

    In the storage amount detection means (70), the phototransistor (73) detects the luminous intensity of light that has passed through the first transparent window (64) and the second transparent window (65) in order from the light emitting LED (72). Then, the amount of dust stored (that is, the degree of filling) in the storage unit (62) is detected according to the detected light intensity. That is, when the amount of stored dust is small, the transmittance of light from the first transparent window (64) to the second transparent window (65) in the storage section (62) increases, and the detected luminous intensity increases. Conversely, if the amount of stored dust is large, the transmittance of light from the first transparent window (64) to the second transparent window (65) in the storage part (62) decreases, and the detected light intensity decreases. Therefore, according to this storage amount detection means (70), the presence or absence of dust in the storage part (62) can be detected.

    As shown in FIGS. 1 and 2, the dust transfer means (80) includes the transfer duct (81), the transfer fan (82), the exhaust port (83), and the suction duct (84). And a vacuum cleaner insertion opening (85).

    The transfer duct (81) has one end on the inflow side connected to the transfer port (67) of the storage section (62) in the dust storage container (60), and the other end on the outflow side, which will be described later. (90) connected. The transport duct (81) is formed of a flexible tube.

    The suction side of the transfer fan (82) is connected to a dust collection box (90). This connection position is the end of the dust collection box (90) opposite to the connection position of the transfer duct (81). The blower side (blowing side) of the transfer fan (82) is connected to an exhaust port (83) that penetrates the casing (10). The transfer fan (82) is for transferring dust stored in the dust storage container (60) to the dust collection box (90) together with air by suction. During the transport operation, air (room air) is introduced from the outside through the mesh portion (66) in the dust container (60). Thus, in the present embodiment, the dust in the dust container (60) is transported to a predetermined position by the air flow generated by the transport fan (82).

    The suction duct (84) has one end on the inflow side connected to the end on the same side as the connection position of the transfer duct (81) in the dust collection box (90). The other end on the outflow side of the suction duct (84) is connected to a cleaner insertion port (85) formed in the decorative panel (11). This vacuum cleaner insertion port (85) is an opening through which a hose or the like of a vacuum cleaner is inserted and sucked. The suction duct (84) is formed of a flexible tube. With this configuration, the dust conveyed to the dust collection box (90) is collected by the vacuum cleaner. Also during the collecting operation, air (room air) is introduced from the outside through the mesh portion (66) in the dust container (60).

    As described above, the air supply action by the mesh portion (66) of the dust container (60) provides an appropriate pressure balance between the dust container (60) and the dust collection box (90). The discharge operation (collection operation to the vacuum cleaner) is appropriately performed.

    As shown in FIGS. 1 and 2, the dust collection box (90) is configured to transport and store the dust in the dust container (60) as described above. The dust collection box (90) is formed in a slightly elongated, substantially rectangular parallelepiped shape, and is disposed below the partition plate (25) like the dust container (60). And the dust collection box (90) is arrange | positioned along the one end side of a partition plate (25) so that it may not cover the air filter (30) planarly. This does not hinder the flow of air sucked from the suction grill (12).

The dust collection box (90) has a larger volume than the dust container (60). In the dust collection box (90), the area of the connection side portion of the transfer fan (82) is smaller than that of other portions in plan view. The side plate on the air filter (30) side of the dust collection box (90) is formed in an arc shape corresponding to the outer periphery of the air filter (30). Further, the dust collection box (90) is provided with a filter (91) at the connection portion of the transfer fan (82). Therefore, the dust conveyed to the dust collection box (90) does not flow out from the exhaust port ( 83 ).

-Driving action-
Next, the operation | movement operation | movement in the said indoor unit (1) is demonstrated, referring FIGS. 9-11. The indoor unit (1) is configured to be switchable between a normal operation for performing air conditioning and a filter cleaning operation for cleaning the air filter (30).

<Normal operation>
In the normal operation, as shown in FIG. 9C, the rotating brush (51) is rotated and the brush (51b) is positioned on the cleaning brush (52) side. That is, the rotating brush (51) is rotated to a position where the brush (51b) of the rotating brush (51) does not contact the air filter (30), and the non-brush surface of the rotating brush (51) (that is, the brush (51b)) An outer peripheral surface of the shaft (51a) not provided is made to face the air filter (30). The air filter (30) and the transfer fan (82) are in a stopped state.

    In this state, the indoor fan (21) is driven. Then, in the indoor unit (1), the indoor air sucked from the suction port (13) passes through the air filter (30) and flows into the bell mouth (24). When air passes through the air filter (30), dust in the air is captured by the mesh member (37) of the air filter (30). The air flowing into the bell mouth (24) is blown out from the indoor fan (21). The blown air is cooled or heated by exchanging heat with the refrigerant in the indoor heat exchanger (22), and then supplied into the room from each outlet (14). Thereby, indoor cooling or heating is performed.

    In this normal operation, as described above, the brush (51b) of the rotating brush (51) and the air filter (30) are in a non-contact state. Therefore, it is possible to prevent the brush (51b) from being deteriorated due to the contact with the air filter (30). Thereby, durability of a rotating brush (51) improves.

<Filter cleaning operation>
In the filter cleaning operation, the compressor is stopped in the refrigerant circuit, and the refrigerant does not circulate. In this filter cleaning operation, “dust removal operation”, “brush cleaning operation”, “dust transport operation”, and “dust discharge operation” can be switched.

    The “dust removal operation” is an operation for removing dust trapped by the air filter (30). The “brush cleaning operation” is an operation for removing dust adhering to the rotating brush (51). The “dust transfer operation” is an operation of transferring dust from the dust container (60) to the dust collection box (90). The “dust discharge operation” is an operation for discharging dust from the dust collection box (90) to the outside of the casing (10), that is, an operation for collecting the dust in the dust collection box (90) with a vacuum cleaner.

    In the present embodiment, “dust removal operation” and “brush cleaning operation” are performed alternately. First, in the “dust removal operation”, the indoor fan (21) is stopped. Then, as shown in FIG. 9A, the rotating brush (51) is rotated to bring the brush (51b) into contact with the air filter (30). In this state, the air filter (30) is rotated in the direction indicated by the arrow (counterclockwise) in FIG. That is, the air filter (30) moves so as to face the bristles of the brush (51b) of the rotating brush (51) as indicated by the arrows (outlined) shown in FIG. At this time, the rotating brush (51) remains stopped.

    Then, dust on the air filter (30) is captured by the brush (51b) of the rotating brush (51) (see FIG. 11A). When the lever (44a) of the limit switch (44) of the filter driving means (40) is actuated, the filter driving motor (41) is stopped and the air filter (30) is stopped. That is, the air filter (30) rotates by a predetermined angle and stops. Therefore, the dust in the area | region which passed the brush (51b) of the rotating brush (51) in an air filter (30) is removed. Here, since the bristles of the brush (51b) are inclined to oppose the rotation direction (movement direction) of the air filter (30), dust on the air filter (30) is easily scraped off by the brush (51b). . Therefore, the dust removal efficiency by the rotating brush (51) is improved. When the air filter (30) stops, the “dust removal operation” is switched to the “brush cleaning operation”.

    In the “brush cleaning operation”, with the indoor fan (21) and the rotating brush (51) still stopped, the air filter (30) first rotates in the direction indicated by the arrow (clockwise) in FIG. 9B. . That is, the air filter (30) rotates in the opposite direction to that during the “dust removal operation”, that is, in the same direction as the bristles of the brush (51b) of the rotating brush (51). In the present embodiment, the air filter (30) rotates so as to move by the width of the brush (51b) of the rotating brush (51). Then, dust collected between the air filter (30) and the brush (51b), that is, dust removed from the air filter (30) is uniformly attached to the brush (51b). Thereby, the dust of the air filter (30) is reliably captured by the brush (51b). Therefore, the dust removal efficiency by the rotating brush (51) can be improved.

    Subsequently, in the “brush cleaning operation”, the rotating brush (51) rotates counterclockwise (counterclockwise) in FIG. 11 with the indoor fan (21) stopped. At that time, the rotating brush (51) rotates while dust is captured by the brush (51b). In addition, the rotating brush (51) rotates while the brushes (51b, 52b) of the rotating brush (51) and the cleaning brush (52) are in contact with each other (see FIG. 11B). The rotating brush (51) stops when it rotates by a predetermined rotation angle.

    Subsequently, the rotating brush (51) rotates counterclockwise (that is, clockwise (in the clockwise direction in FIG. 11)). Then, the dust trapped on the brush (51b) of the rotating brush (51) is removed by the brush (52b) of the cleaning brush (52) (see FIG. 11C). This is because the bristles of the brush (52b) of the cleaning brush (52) are inclined downward, that is, the bristles are inclined in a direction opposite to the rotation direction of the rotary brush (51). ) Is scraped off. Further, the main body part (52a) of the cleaning brush (52) is pushed backward by the contact between both brushes (51b, 52b), but the main body part (52a) is rotated by a rotating brush (52c). 51) It is energized to the side. Accordingly, the brushes (51b, 52b) are not separated from each other, and the cleaning brush (52) is appropriately pressed against the rotating brush (51). Therefore, dust is more reliably removed from the brush (51b) of the rotating brush (51). Thus, dust is captured by the brush (52b) of the cleaning brush (52). The rotating brush (51) rotates to the original state (the state shown in FIG. 11A) and stops.

    Subsequently, the rotating brush (51) rotates counterclockwise (counterclockwise) again by a predetermined rotation angle. Then, the dust captured by the brush (52b) of the cleaning brush (52) is scraped off by the brush (51b) of the rotating brush (51) and falls to the storage part (62) of the dust storage container (60). (See FIG. 11D). This is because the bristles of the brush (51b) of the rotating brush (51) are inclined in the rotating direction, so that dust is reliably scraped off from the brush (52b) of the cleaning brush (52). At this time, similarly to the above, since the cleaning brush (52) is appropriately pressed against the rotating brush (51) by the spring portion (52c), dust is more reliably removed from the cleaning brush (52). As described above, the dust trapped by the rotating brush (51) is removed and stored in the storage section (62) of the dust storage container (60). Thereafter, the rotating brush (51) rotates again clockwise (clockwise) to return to the original state (the state shown in FIG. 11A), and the “brush cleaning operation” is temporarily ended.

    When the “brush cleaning operation” is completed, the “dust removal operation” described above is performed again. That is, when the air filter (30) is rotated again and the lever (44a) of the limit switch (44) is actuated again, the air filter (30) is stopped. Thereby, the dust of the area | region which passed the brush (51b) of the rotating brush (51) in an air filter (30) is capture | acquired by the brush (51b) of a rotating brush (51) (state of FIG. 11 (A)). Thus, the “dust removal operation” and the “brush cleaning operation” are alternately repeated. As a result, dust is removed for each predetermined region in the air filter (30). When the dust is removed in the entire area of the air filter (30), the “dust removal operation” and the “brush cleaning operation” are completely completed. For example, when the lever (44a) of the limit switch (44) is actuated a predetermined number of times, it is determined that the air filter (30) has made one revolution, and the above operation ends.

    By the way, every time the above-described “brush cleaning operation” is performed once or several times, the “dust transfer operation” is performed.

    In the “dust transporting operation”, the rotary brush (51) is stopped in the state of FIG. 11 (A), and the air filter (30) is stopped. In this state, the transfer fan (82) is driven. Then, the air in the dust collection box (90) is discharged from the exhaust port (83). Accordingly, the dust in the dust container (60) is conveyed (sucked) together with air to the dust collecting box (90) through the conveying duct (81). Thereafter, “dust removal operation” and “brush cleaning operation” are performed again, and “dust transport operation” is performed. By repeating these operations, dust is gradually stored in the dust collection box (90). When the dust in the dust collection box (90) is full, no matter how many "dust transport operations" are performed, the dust is not transported from the dust storage container (60) to the dust collection box (90). Dust gradually accumulates in the storage container (60). On the other hand, in the dust container (60), the dust storage amount is detected by the storage amount detection means (70). When a predetermined amount of dust accumulates in the storage part (62) of the dust storage container (60) in spite of the "dust transfer operation" being performed, the detection of the phototransistor (73) of the storage amount detection means (70) The luminous intensity is below the set value. Thereby, it is detected that the dust in the dust collection box (90) is full.

    In the filter cleaning operation of the present embodiment, when the full state of the dust collection box (90) is detected as described above, the “dust discharge operation” is performed. In the “dust discharging operation”, the rotary brush (51) is stopped in the state shown in FIG. 11A and the air filter (30) is stopped as in the “dust transporting operation” described above. Further, the transfer fan (82) is also stopped. In this state, the user inserts the vacuum cleaner hose into the vacuum cleaner insertion port (85). By this suction operation, the dust in the dust collection box (90) is sucked into the cleaner through the suction duct (84). At that time, the dust in the dust container (60) is also sucked into the cleaner through the transfer duct (81), the dust collection box (90) and the suction duct (84) in this order. As a result, the dust in the dust collection box (90) and the dust container (60) is collected by the vacuum cleaner. That is, dust such as a dust collection box (90) is discharged out of the casing (10).

-Effect of the embodiment-
In this embodiment, since the dust container (60) is located below the air filter (30), it becomes a resistance (disturbance) in air flow. Therefore, it is necessary to make the dust container (60) as small as possible. Therefore, in the present embodiment, the dust collection box (90) having a larger volume than the dust storage container (60) is provided in a place where air circulation is not hindered, and the dust storage container (60) is provided by the transfer fan (82). Dust was transferred to the dust collection box (90). Thereby, the dust removed from the air filter (30) can be finally stored in a large amount in the dust collection box (90) without bothering the user. As a result, it is possible to reduce the time and effort for dust processing by the user.

    Moreover, since the dust of the air filter (30) is finally stored in the dust collection box (90), the dust storage container (60) can be reduced in size. As a result, the flow resistance of the intake air in the indoor unit (1) can be reduced, and the operation efficiency is improved.

    Furthermore, in this embodiment, since the suction duct (84) and the cleaner insertion port (85) are provided, the dust in the dust collection box (90) can be easily discharged out of the casing (10). it can. Therefore, the trouble of dust processing can be further reduced.

    Moreover, in this embodiment, since the rotating brush (51) is provided in the dust storage container (60), the dust removed by the rotating brush (51) can be reliably temporarily stored in the dust storage container (60). . Further, since the air filter (30) is moved relative to the rotating brush (51), dust can be removed over the entire surface of the air filter (30). In this configuration, the volume and arrangement of the dust container (60) are further limited. However, in this embodiment liquid, the dust container (60) can be easily dusted into the dust collection box (90). Therefore, a large amount of dust can be effectively stored.

    In the present embodiment, the brush (51b) of the rotating brush (51) is made of a pile fabric. Therefore, since the bristle of the brush (51b) is short, the installation space for the rotating brush (51) can be reduced. Further, since the bristle of the brush (51b) is short, and since the brush (51b) is provided only in a part of the circumferential direction of the rotating brush (51), the dust container (60) The air flow resistance can be reduced. As a result, the transfer efficiency of the dust transfer operation and the discharge efficiency of the dust discharge operation can be improved.

    In the present embodiment, the brush (51b) of the rotating brush (51) and the air filter (30) are in a non-contact state during normal operation in which the air filter (30) is not cleaned. Therefore, it is possible to prevent deterioration due to the long-time contact with the air filter (30) of the brush (51b). Thereby, durability of a rotating brush (51) can be improved and a dust removal function can be maintained long.

    In particular, in the present embodiment, since the brush (51b) is provided in a part of the circumferential direction in the rotating brush (51), the rotating brush (51) and the air can be easily rotated only by rotating the rotating brush (51). The filter (30) can be brought into a non-contact state. Further, since the brush (51b) is provided only in a part of the circumferential direction of the rotating brush (51), the material cost of the brush (51b) can be reduced, and the cost of the dust removing means (50) can be reduced. it can.

    In the present embodiment, the dust removing means (50) is provided with the cleaning brush (52). Therefore, the dust trapped by the rotating brush (51) can be reliably removed and stored in the dust container (60). Therefore, in the rotating brush (51), it is possible to suppress a decrease in the dust removal function due to an increase in the amount of dust trapped. Therefore, the dust removal efficiency for the air filter (30) can be improved.

    Furthermore, in this embodiment, the air filter (30) is rotated by a predetermined angle to alternately perform the dust removal operation and the brush cleaning operation, so that the dust removal efficiency is maintained high throughout the air filter (30). can do. Therefore, the dust of the whole air filter (30) can be removed reliably.

-Modification of the embodiment-
Next, a modification of the above embodiment will be described.

<Modification 1>
In the first modification, as shown in FIGS. 12 and 13, the configuration of the dust transfer means (80) in the above embodiment is changed.

    Specifically, in the present modification, the transfer fan (82) is connected to the end of the dust container (60). That is, the blower side (outlet side) of the transfer fan (82) is connected to the end of the dust container (60) opposite to the connection position of the transfer duct (81). The dust collection box (90) is connected to the exhaust port (83) at the end opposite to the connection position of the transfer duct (81) and the suction duct (84). A filter (91) is provided at the connecting portion of the dust collection box (90).

    In this modification, air is blown out from the transfer fan (82) to the dust container (60) in the “dust transfer operation”. As a result, the dust in the dust container (60) is transferred to the dust collection box (90) through the transfer duct (81) together with the air. At that time, the air in the dust collection box (90) is discharged through the filter (91) to the exhaust port (83). Thereby, the pressure balance of the dust container (60) and the dust collection box (90) becomes appropriate. Moreover, since the filter (91) is provided in the dust collection box (90), the conveyed dust does not flow out to the exhaust port (83). Thus, in this modification, the dust stored in the dust container (60) is transferred to the dust collection box (90) by the blowing action of the transfer fan (82). Other configurations, operations, and effects are the same as those in the above embodiment.

<Modification 2>
In the second modified example, a wind speed sensor (69) is provided instead of the stored amount detecting means (70) in the dust container (60) of the embodiment and the first modified example.

    Specifically, in the dust container (60) of the above embodiment, a wind speed sensor (69) is provided in the vicinity of the inside of the mesh part (66) as shown in FIG. Moreover, in the dust container (60) of the said modification 1, as shown in FIG. 15, the wind speed sensor (69) is provided in the blower outlet vicinity of the fan (82) for conveyance. That is, in any dust storage container (60), the wind speed sensor (69) is arranged on the upstream side of the air flow from the storage portion (62) in which dust is stored. This wind speed sensor (69) is a flow velocity detecting means for detecting the flow velocity of air (that is, the wind velocity) by the suction action or the blowing action of the transfer fan (82).

    And in this modification, the dust full state of the dust collection box (90), the clogging in the transfer duct (81), etc. are detected based on the detection value of the wind speed sensor (69). Specifically, during the “dust transfer operation”, the wind speed in the dust container (60) is detected by the wind speed sensor (69). Here, when the dust collection box (90) does not collect much dust, the detection value of the wind speed sensor (69) is low. That is, since there is almost no dust in the air passage from the dust container (60) to the dust collection box (90), the air flow resistance is reduced and the wind speed is increased. After that, as the dust in the dust container (60) is transferred to the dust collection box (90) together with the air, the amount of dust stored in the dust collection box (90) increases, and the air flow resistance increases. The wind speed decreases. When the dust in the dust collection box (90) becomes full (predetermined amount), the detection value (wind speed) of the wind speed sensor (69) becomes a predetermined value or less. Thereby, it is detected that the dust in the dust collection box (90) is full. When the full state of the dust collecting box (90) is detected, the transfer fan (82) is stopped, and the “dust discharging operation” similar to the above embodiment is performed. In this way, the start timing of the “dust discharge operation” is appropriately measured.

    In addition, when clogging occurs in the transfer duct (81) and the dust container (60), the air flow resistance increases and the wind speed decreases. Therefore, it can be inferred that the transport duct (81) or the like is clogged when the detected value (wind speed) of the wind speed sensor (69) is equal to or lower than the predetermined value. Then, after the clog is removed by inspection, the “dust transporting operation” is resumed.

    As described above, since the wind speed sensor (69) is provided in the dust container (60), the change in air flow resistance in the dust container (60) and the transport duct (81) during the "dust transport operation". Can be detected. Based on the change in the flow resistance, it is possible to detect the full state of dust in the dust collection box (90). As a result, it is possible to appropriately measure the start timing of the “dust discharge operation”.

    Further, since it is possible to estimate the clogging of dust in the transfer duct (81) and the like based on the detection value of the wind speed sensor (69), it is possible to detect a problem in air circulation at an early stage. Therefore, a highly reliable indoor unit (1) can be provided.

    In addition, since the wind speed sensor (69) is provided upstream of the storage part (62) in the dust storage container (60), the air flow velocity in a place where no dust exists can be detected. Thereby, since the sensing of the wind speed sensor (69) is not affected by dust, the accuracy of detecting the wind speed is increased. As a result, the start timing of the “dust discharge operation” can be measured more appropriately. Furthermore, the deterioration of the wind speed sensor (69) due to dust can be suppressed. As a result, the reliability of the indoor unit (1) is further improved.

    In this modified example, the wind speed sensor (69) may be disposed at a location other than the upstream side in the dust container (60), or may be disposed in the transport duct (81) or the dust collection box (90). It may be arranged. Even in this case, similarly, the full state of the dust collection box (90) can be detected, and clogging with dust can be detected at an early stage.

<< Other Embodiments >>
The above embodiment may be configured as follows.

    In the above embodiment, the air filter (30) is rotated with respect to the rotating brush (51) during the dust removing operation in the filter cleaning operation. However, the present invention is directed to the dust storage container with respect to the air filter (30). (60) (including the rotating brush (51) and the cleaning brush (52)) may be moved. In this case, the dust container (60) revolves around the shaft insertion part (33) of the air filter (30). That is, the present invention only needs to be configured such that the air filter (30) and the rotating brush (51) move relatively during the dust removal operation.

    Moreover, in the said embodiment, although the air filter (30) shall be formed circularly, not only this but the air filter (30) may be formed rectangularly. In this case, for example, the air filter (30) moves linearly with respect to the rotating brush (51).

    In the above embodiment, the indoor unit (1) installed on the indoor ceiling has been described. However, the present invention is not limited to this, and the present invention is also applicable to a so-called wall-mounted indoor unit installed on an indoor wall. be able to.

    Moreover, in the said embodiment, although the indoor unit (1) which has arrange | positioned the indoor heat exchanger (22) in the blowing side of the indoor fan (21) was demonstrated, the indoor heat exchanger (22) is an air filter in this invention. Even the indoor unit (1) disposed between the (30) and the indoor fan (21) can be applied.

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

    As described above, the present invention is useful as an indoor unit of an air conditioner having a dust removing function of an air filter.

It is a longitudinal cross-sectional view which shows the structure of the indoor unit which concerns on embodiment. It is the cross-sectional view which looked at the structure of the indoor unit which concerns on embodiment from upper direction. It is a perspective view which shows the structure of the partition plate which concerns on embodiment, an air filter, and a dust storage container. It is sectional drawing which shows the attachment part of the air filter which concerns on embodiment. It is a perspective view which shows the structure of the filter drive means which concerns on embodiment. It is a perspective view which shows the structure of the dust removal means and dust storage container which concern on embodiment, seeing from upper direction. It is a cross-sectional view which shows the structure of the dust storage container which concerns on embodiment. It is a cross-sectional view which shows the structure of the storage amount detection means which concerns on embodiment in relation to a dust storage container. It is a figure which shows roughly the relationship between the air filter which concerns on embodiment, and a dust removal means, (A) and (B) show the state at the time of filter cleaning operation, (C) shows the state at the time of normal operation, respectively. It is a cross-sectional view showing the relationship between the air filter and the dust removing means during the dust removing operation according to the embodiment. It is a cross-sectional view showing the operation of the dust removing means during the brush cleaning operation according to the embodiment. It is a longitudinal cross-sectional view which shows the structure of the indoor unit which concerns on the modification 1 of embodiment. It is the cross-sectional view which looked at the structure of the indoor unit which concerns on the modification 1 of embodiment from upper direction. It is a longitudinal cross-sectional view which shows the structure of the indoor unit which concerns on the modification 2 of embodiment. It is a longitudinal cross-sectional view which shows the structure of the indoor unit which concerns on the modification 2 of embodiment.

1 Indoor unit
10 Casing
21 Indoor fan
22 Indoor heat exchanger
30 Air filter
40 Filter drive means (moving means)
50 Dust removal means
51 Rotating brush (brush member)
51b brush
60 Dust storage container
69 Wind speed sensor (flow velocity detection means)
81 Transport duct
82 Transport fan
84 Suction duct
85 Vacuum cleaner insertion slot (85)

Claims (6)

In the casing (10), an indoor heat exchanger (22), an indoor fan (21) for sucking air from the room, an air filter (30) provided on the suction side of the indoor fan (21), and the air filter An air conditioner indoor unit comprising dust removing means (50) for removing dust trapped in (30),
A dust container (60) provided in the casing (10) for storing the dust removed by the dust removing means (50);
A dust collection box (90) having a larger volume than the dust storage container (60) and connected by the dust storage container (60) and a transfer duct (81);
Is connected to the casing provided in (10) in Rutotomoni the dust collection box (90), the dust capturing through the transfer duct (81) by suction action the dust stored in the dust container (60) A transport fan (82) for transporting to the collection box (90) ;
The dust collection box (90) communicates with the suction duct (84), and the dust conveyed to the dust collection box (90) is sucked from the outside through the suction duct (84) by a vacuum cleaner. A vacuum cleaner insertion port (85) for
The transfer fan (82) is connected to the side opposite to the connection side of the transfer duct (81) in the dust collection box (90),
The indoor unit of an air conditioner, wherein the dust collection box (90) is provided with a filter (91) at a connection portion of the transfer fan (82) . In the casing (10), an indoor heat exchanger (22), an indoor fan (21) for sucking air from the room, an air filter (30) provided on the suction side of the indoor fan (21), and the air filter An air conditioner indoor unit comprising dust removing means (50) for removing dust trapped in (30),
A dust container (60) provided in the casing (10) for storing the dust removed by the dust removing means (50);
A dust collection box (90) having a larger volume than the dust storage container (60) and connected by the dust storage container (60) and a transfer duct (81);
Connected to the casing (10) provided in Rutotomoni the dust container (60), the dust collection through the transfer duct (81) by the blowing action of dust stored in the dust container (60) A transport fan (82) for transporting to the box (90) ;
The dust collection box (90) communicates with the suction duct (84), and the dust conveyed to the dust collection box (90) is sucked from the outside through the suction duct (84) by a vacuum cleaner. A vacuum cleaner insertion port (85) for
The indoor unit of the air conditioner, wherein the transfer fan (82) is connected to a side of the dust container (60) opposite to the connection side of the transfer duct (81). unit. In claim 1 or 2 ,
The dust removing means (50) includes a brush member (51) provided in the dust container (60) and in contact with the air filter (30), and the air filter (30) with respect to the brush member (51). And a moving means (40) for moving the air conditioner indoor unit. In claim 3 ,
The indoor unit of an air conditioner, wherein the brush member (51) of the dust removing means (50) includes a brush (51b) made of a pile fabric and contacting the air filter (30). In claim 1 or 2 ,
Air provided in the dust storage container (60), the transfer duct (81) or the dust collection box (90) and provided with flow velocity detection means (69) for detecting the flow velocity of air The indoor unit of the harmony device. In claim 5 ,
The indoor unit of an air conditioner, wherein the flow velocity detection means (69) is provided upstream of the dust storage part of the dust storage container (60).

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