JP2011043293A - Indoor unit of air conditioning device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To surely guide dust removed from an air filter to a storage space in an indoor unit of an air conditioning device having a function for removing the dust attached to the air filter. <P>SOLUTION: A dust storage container (60) includes a receiving space (59) for receiving a rotary brush (51), and the storage space (58) communicated with the receiving space (59) at an oblique lower position to the vertical direction of the rotary brush (51) to store the dust removed by the rotary brush (51). A cleaning brush (52) is disposed at a side opposite to the storage space (58) through the rotary brush (51), in the receiving space (59). <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an indoor unit of an air conditioner having a function of removing dust attached to an air filter.

  Conventionally, an indoor unit of an air conditioner having a function of removing dust adhering to an air filter (so-called cleaning function) is known. For example, Patent Document 1 describes an indoor unit of this type of air conditioner.

  Specifically, FIG. 10 of Patent Document 1 describes a rotating brush for removing dust from the suction filter and a dust storage container for collecting dust removed from the suction filter by the rotating brush. A collection opening in which a rotating brush is disposed is formed on the upper surface portion of the dust container. A cleaning brush for scraping off dust from the brush portion of the rotating brush is provided inside the dust container.

JP 2008-215644 A

  By the way, when a rotating brush is used to remove dust adhering to the air filter, the upper portion that accommodates the rotating brush should not be obstructed by the dust accumulated in the dust container. On the other hand, it is conceivable to bulge the lower portion of the dust storage container for storing dust to the side. In other words, it is possible to suppress the accumulation of dust around the rotating brush by shifting the dust storing space in the horizontal direction with respect to the rotating brush, instead of forming a space for storing the dust directly under the rotating brush. It is.

  When the dust container is configured in this way, a cleaning brush that contacts the rotating brush and removes dust adhering to the rotating brush is disposed on the side closer to the space for storing the dust, that is, the lower side of the dust container. It can be considered to be provided on the bulging side where the portion bulges. However, in that case, rather, dust accumulates on the side opposite to the bulging side. This will be described below.

  Here, when the cleaning brush is provided, the rotating brush has a rotating shaft for switching between a state where the brush portion is exposed to the outside of the dust container from the opening and a state where the brush portion is in contact with the cleaning brush. Is driven to rotate in both directions around. In this rotating brush, the dust removed from the air filter may be continuous in a band shape. The belt-like dust has a shape bent toward the rotating brush while the rotating brush is driven to rotate in both directions around the rotating shaft. For this reason, when the belt-like dust reaches the inner surface of the dust container, the belt-like dust is guided to the space opposite to the bulging side. For example, when belt-like dust comes off the rotating brush, it may remain in the space on the opposite side to the bulging side. Further, for example, when air is sent to the inside of the bulging portion in the dust container and the dust is transported outside the dust container, the belt-like dust remaining in the space opposite to the bulging side is removed from the air. It may be impossible to convey due to the flow of

  The present invention has been made in view of such a point, and an object of the present invention is to move dust removed from the air filter to the storage space side in an indoor unit of an air conditioner having a function of removing dust attached to the air filter. It is to be able to guide reliably.

  In order to solve the above-described problem, in the present invention, the arrangement of the cleaning brush is devised so that the belt-like dust is reliably guided toward the storage space.

  Specifically, the present invention removes dust adhered to the indoor fan (21), the air filter (30) that captures dust in the air sucked into the indoor fan (21), and the air filter (30). An air conditioner comprising: a rotating brush (51) having a brush portion (51b) for carrying out; and a dust storage container (60) for storing dust removed from the air filter (30) by the rotating brush (51) The following solutions were taken for the indoor unit of the device.

That is, the first invention is a cleaning brush (52) for removing dust adhering to the surface of the brush part (51b) by contacting the brush part (51b) when the rotating brush (51) rotates. With
The dust container (60) communicates with the housing space (59) at a position obliquely below the housing space (59) for housing the rotating brush (51) and the vertical direction of the rotating brush (51). A storage space (58) for storing the dust removed by the rotating brush (51).
The cleaning brush (52) is disposed on the opposite side of the storage space (58) in the housing space (59) with the rotating brush (51) in between.

  In the first invention, when the rotating brush (51) rotates, the cleaning brush (52) contacts the brush portion (51b). Thereby, the dust adhering to the brush part (51b) surface is removed. The dust container (60) has a storage space (59) for storing the rotating brush (51) and a storage space (58) for storing the dust removed by the rotating brush (51). The storage space (58) communicates with the accommodation space (59) at a position obliquely below the vertical direction of the rotating brush (51). The cleaning brush (52) is disposed on the opposite side of the storage space (58) across the rotating brush (51) in the accommodation space (59).

  With such a configuration, even when the dust removed from the air filter (30) is continuous in a band shape, the belt-like dust can be reliably guided to the storage space (58) side. Specifically, when the cleaning brush (52) is disposed on the side close to the storage space (58), the belt-like dust is generated while the rotating brush (51) is driven to rotate in both directions around the rotation axis. The shape is bent toward the rotating brush (51). For this reason, when the belt-like dust reaches the inner surface of the accommodation space (59), it is guided to the space on the opposite side to the storage space (58). When the belt-like dust comes off the rotating brush (51), it may remain in the space opposite to the storage space (58).

  On the other hand, in the present invention, the cleaning brush (52) is disposed on the opposite side of the storage space (58) with the rotary brush (51) interposed therebetween, so that the belt-like dust is placed on the rotary brush (51) side. When it becomes a bent shape and reaches the inner surface of the accommodation space (59), the tip of the belt-like dust comes to face the storage space (58). As a result, when the belt-like dust is removed from the rotating brush (51), the dust can be reliably guided to the storage space (58), and the dust can be prevented from remaining in the accommodation space (59). .

According to a second invention, in the first invention,
The rotating brush (51) performs a brush cleaning operation in which the brush portion (51b) is reciprocated in the rotation direction in order to remove dust adhering to the brush portion (51b) by the cleaning brush (52). It is comprised so that it may be comprised.

  In 2nd invention, the brush cleaning operation | movement which reciprocates a brush part (51b) in the rotation direction is performed by the rotating brush (51). Thereby, the dust adhering to the brush part (51b) is removed by the cleaning brush (52).

  With such a configuration, the brush cleaning operation is performed, and the brush (51b) is reciprocated in the rotating direction of the rotating brush (51), so that the cleaning brush (52) adheres to the brush portion (51b). The removed dust can be reliably removed.

  According to the present invention, since the cleaning brush (52) is disposed on the opposite side of the storage space (58) with the rotary brush (51) in between, the belt-like dust is bent toward the rotary brush (51). When the shape reaches the inner surface of the accommodation space (59), the tip of the belt-like dust comes to face the storage space (58). As a result, when the belt-like dust is removed from the rotating brush (51), the dust can be reliably guided to the storage space (58), and the dust can be prevented from remaining in the accommodation space (59). .

It is a piping system figure showing the composition of the air harmony device provided with the indoor unit concerning the embodiment of the present invention. It is a longitudinal cross-sectional view which shows the structure in an indoor unit. It is the perspective view which looked at the decorative panel from the room inner side. It is the XX sectional view taken on the line in FIG. It is a perspective view which shows the structure of the vent hole of a partition plate, an air filter, and a dust storage container. It is the perspective view which looked at the dust removal mechanism and the dust storage container from the upper part. It is the perspective view which looked at the dust container from the lower part. It is the YY sectional view taken on the line in FIG. It is an expanded sectional view of the duct for introduction. It is sectional drawing which shows operation | movement of the damper of a dust conveyance mechanism. It is a figure which shows roughly the relationship between an air filter and a dust removal mechanism, (a) shows the state at the time of normal operation, (b) and (c) show the state at the time of filter cleaning operation, respectively. FIG. 7 is a diagram showing an operation of the dust removal mechanism during the dust removal operation in the ZZ line cross section in FIG. 6. It is a figure which shows operation | movement of the dust removal mechanism at the time of brush cleaning operation | movement.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. It should be noted that the following description of the preferred embodiment is merely illustrative in nature and is not intended to limit the present invention, its application, or its use.

  This embodiment relates to an air conditioner (1) provided with an indoor unit (3) according to the present invention. In this air conditioner (1), the indoor unit (3) is installed on the ceiling of the indoor space. Hereinafter, the configuration of the air conditioner (1) according to the present embodiment will be described first, and then the configuration of the indoor unit (3) will be described.

<overall structure>
As shown in FIG. 1, the air conditioner (1) includes an outdoor unit (2) and an indoor unit (3). The outdoor unit (2) is provided with a compressor (4), an outdoor heat exchanger (5), an expansion valve (6), a four-way switching valve (7), and an outdoor fan (8). The indoor unit (3) is provided with an indoor heat exchanger (22) and an indoor fan (21).

  In the outdoor unit (2), the discharge side of the compressor (4) is connected to the first port (P1) of the four-way switching valve (7). The suction side of the compressor (4) is connected to the third port (P3) of the four-way switching valve (7).

  The outdoor heat exchanger (5) is configured as a cross fin type fin-and-tube heat exchanger. One end of the outdoor heat exchanger (5) is connected to the fourth port (P4) of the four-way switching valve (7). The other end of the outdoor heat exchanger (5) is connected to the liquid side closing valve (9a).

  The outdoor fan (8) is provided in the vicinity of the outdoor heat exchanger (5). In the outdoor heat exchanger (5), heat exchange is performed between the outdoor air sent by the outdoor fan (8) and the refrigerant flowing through the heat transfer tube of the outdoor heat exchanger (5). Between the outdoor heat exchanger (5) and the liquid side closing valve (9a), an expansion valve (6) having a variable opening is provided. The second port (P2) of the four-way selector valve (7) is connected to the gas side shut-off valve (9b).

  The four-way selector valve (7) is in a first state in which the first port (P1) and the second port (P2) communicate with each other and the third port (P3) and the fourth port (P4) communicate with each other. (The state indicated by the solid line in FIG. 1), the second port (P1) and the fourth port (P4) communicate with each other, and the second port (P2) and the third port (P3) communicate with each other. The state (state indicated by a broken line in FIG. 1) can be switched.

  In the air conditioner (1), the heating operation is performed when the four-way switching valve (7) is in the first state, and the cooling operation is performed when the four-way switching valve (7) is in the second state. In the heating operation, in the refrigerant circuit shown in FIG. 1, a vapor compression refrigeration cycle in which the outdoor heat exchanger (5) functions as an evaporator and the indoor heat exchanger (22) functions as a condenser is performed. On the other hand, in the cooling operation, a vapor compression refrigeration cycle in which the outdoor heat exchanger (5) functions as a condenser and the indoor heat exchanger (22) functions as an evaporator is performed in the refrigerant circuit shown in FIG.

<Configuration of indoor unit>
The configuration of the indoor unit (3) will be described in detail with reference to FIGS. As shown in FIG. 2, the indoor unit (3) includes a main unit (10) having an indoor fan (21) and an indoor heat exchanger (22), and an indoor side (lower side) of the main unit (10). The cleaning unit (100) is provided, and a decorative panel (11) that covers the indoor side (lower side) of the cleaning unit (100). That is, the indoor unit (3) is formed by laminating the main unit (10), the cleaning unit (100), and the decorative panel (11) in order from the top.

  The main unit (10) includes a box-shaped main casing (18) installed so as to open toward the room. An indoor fan (21), an indoor heat exchanger (22), a drain pan (23), and a bell mouth (24) are disposed in the main casing (18).

  A heat insulating material (17) is laminated on the inner surface of the main casing (18). The main casing (18) is suspended and supported from the ceiling surface on the back of the ceiling with the opening side facing the indoor side.

  The indoor fan (21) is a so-called turbo fan. The indoor fan (21) is disposed in the vicinity of the center of the main casing (18) of the main unit (10) and is located above the suction port (13) of the decorative panel (11). 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 main casing (18). The impeller (21b) is connected to the rotation shaft of the fan motor (21a).

  A bell mouth (24) is provided below the indoor fan (21) so as to communicate with the suction port (13). The bell mouth (24) partitions the space upstream of the indoor heat exchanger (22) into an indoor fan (21) side and a suction grille (12) side in the indoor unit (3).

  Further, an opening (not shown) is formed in the body partition plate constituted by the bell mouth (24) and the drain pan (23) at a position corresponding to one of the four corners of the rectangular parallelepiped body casing (18). ) Is formed. This opening constitutes an introduction port (86d) of an introduction duct (86) described later (see FIG. 9).

  The indoor heat exchanger (22) is formed in a square shape in plan view, and is disposed in the main body casing (18) so as to surround the indoor fan (21). In the indoor heat exchanger (22), heat exchange is performed between the indoor air (blown air) sent by the indoor fan (21) and the refrigerant flowing through the heat transfer tubes of the indoor heat exchanger (22).

  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 cleaning unit (100) includes an air filter (30), a dust removal mechanism (50), a dust transport mechanism (80), a dust collection box (90), etc. in a substantially rectangular casing (101) in plan view. Is arranged. The cleaning unit (100) removes dust adhering to the air filter (30) located on the suction side of the indoor fan (21) by the dust removing mechanism (50) and removes the removed dust by the dust transport mechanism (80). It is configured to be transferred into the dust collection box (90). The dust removed from the air filter (30) is finally stored in the dust collection box (90).

  The casing (101) is formed in the same size as the main casing (18) of the main unit (10) in plan view. The casing (101) is disposed on the indoor side of the main casing (18) with the seal member (102) sandwiched between the casing (101) and the main casing (18). Further, a decorative panel (11) is attached to the indoor side of the casing (101) with a seal member (103) interposed therebetween.

  The casing (101) is formed with four air passages (101a) along each side. Each air passage (101a) communicates with the space outside the indoor heat exchanger (22) in the main casing (18). The air that has passed through the indoor heat exchanger (22) flows through each air passage (101a). The air flowing through the air passage (101a) is supplied to the indoor space through the blower outlet (14) of the decorative panel (11). A portion of the casing (101) that forms the inner side of the air passage (101a) supports the drain pan (23) from below via a seal member (104).

  As shown in FIG. 3, the decorative panel (11) is formed in a rectangular plate shape in plan view. The decorative panel (11) has a plan view shape that is slightly larger than the plan view shapes of the main body casing (18) and the casing (101). As described above, the decorative panel (11) is attached so as to cover the lower side of the casing (101) with the seal member (103) interposed therebetween. The decorative panel (11) is exposed to the indoor space.

  The decorative panel (11) is formed with one inlet (13) and four outlets (14). The suction port (13) is formed in a substantially rectangular shape at the center of the decorative panel (11). A suction grill (12) having a slit portion (12a) is attached to the suction port (13).

  On the other hand, the said blower outlet (14) is formed in the elongate rectangular shape. Each blower outlet (14) is provided along each side of the decorative panel (11) corresponding to the air passage (101a) of the cleaning unit (100). Each air outlet (14) is provided with a wind direction adjusting plate (15). The wind direction adjusting plate (15) is configured to rotate and adjust the wind direction (the blowing direction).

  The suction grill (12) is provided with a nozzle insertion part (110) for inserting a nozzle of a vacuum cleaner. This nozzle insertion part (110) is comprised so that the nozzle of a cleaner can be inserted so that the dust stored in the dust collection box (90) of the cleaning unit (100) can be collected with a cleaner.

<Configuration of cleaning unit>
Next, the configuration in the cleaning unit (100) will be described in detail with reference to FIGS. The cleaning unit (100) is a unit for cleaning the air filter (30) located on the suction side of the indoor fan (21). The cleaning unit (100) includes an air filter (30), a dust removal mechanism (50), a dust transport mechanism (80), a dust collection box (90), etc. in a substantially rectangular casing (101) in plan view. It is arranged.

  Further, the cleaning unit (100) is provided with a partition plate (25) so as to cover a lower portion of the bell mouth (24). For example, as shown in FIG. 2, 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 fan (21) into the indoor fan (21) side including the bell mouth (24) and the suction grille (12) side.

  As shown in FIG. 5, 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). The air filter (30) is disposed so as to cover the ventilation hole (26) from below. That is, the partition plate (25) is provided so as to close the space between the inner surface of the side wall of the casing (101) and the air filter (30). As a result, the air sucked from the suction port (13) always passes through the air filter (30). Therefore, dust contained in the air upstream of the partition plate (25) can be prevented from flowing into the downstream side of the partition plate (25) without being captured by the air filter (30).

  The vent hole (26) is partitioned in a sector shape by four radial beam portions (27) extending in the radial direction. The respective radial beam portions (27) are connected to each other at the circular center of the vent hole (26), and a cylindrical filter rotation shaft (28) is formed to project downward in that portion. The filter rotation shaft (28) serves as a rotation shaft when the air filter (30) rotates. Moreover, two filter pressers (29) for pressing the air filter (30) from above are provided in one of the radial beam portions (27).

  The air filter (30) is formed in a disk shape, and is attached to the partition plate (25) from the lower side of the vent hole (26). The outer diameter of the air filter (30) is larger than the outer diameters of the bell mouth (24) and the vent hole (26).

  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). On the other hand, a cylindrical shaft insertion portion (33) supported by six radial ribs (34) extending radially in the radial direction is provided at the center of the filter body (31). That is, each radial rib (34) extends radially from the shaft insertion portion (33) and is connected to the filter body (31). In addition, an annular inner circumferential rib (35) and outer circumferential rib (36) arranged concentrically with the filter body (31) are provided inside 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 inside 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 a filter presser (29) that abuts against the upper surface of each circumferential rib (35, 36). Accordingly, the air filter (30) is pressed against the rotating brush (51) described later. Therefore, the dust removal efficiency by the dust removal mechanism (50) can be improved.

  As shown in FIG. 5, the air filter (30) is fitted so that the shaft insertion portion (33) can rotate with respect to the filter rotation shaft (28). A dust container (60) of the dust removal mechanism (50) is disposed below the air filter (30), and the dust filter is stored in a state where the air filter (30) is fitted to the filter rotating shaft (28). The filter mounting portion (68) of the container (60) and the filter rotating shaft (28) are fixed by a set screw (28a). Thus, the air filter (30) is held between the partition plate (25) and the dust container (60).

  As shown in FIG. 4, a filter drive motor (40) for rotationally driving the air filter (30) is provided in the vicinity of the air filter (30). A drive gear (not shown) is provided on the drive shaft of the filter drive motor (40) and meshes with the gear portion (32) of the air filter (30). A limit switch (not shown) detects the rotation of the filter drive motor (40) to detect when the dust removal mechanism (50) is operated according to the rotation speed of the filter drive motor (40). Abnormality detection can be performed when the filter drive motor (40) is not rotating.

  Next, the dust removal mechanism (50), the storage amount detection mechanism (70), the dust transport mechanism (80), and the dust collection box (90) will be described.

  The dust removing mechanism (50) is for removing dust trapped by the air filter (30). As shown in FIGS. 6 and 8, the dust removing mechanism (50) temporarily stores the rotating brush (51), the cleaning brush (52), the brush drive mechanism (53), and the removed dust. And a dust container (60). The rotating brush (51) and the cleaning brush (52) are disposed in the opening (63) of the dust container (60).

  The rotating brush (51) is for removing dust adhering to the air filter (30), and is formed on a cylindrical shaft (51a) provided rotatably and on an outer peripheral surface of the shaft (51a). And a brush part (51b). The brush part (51b) is provided only in a partial region in the circumferential direction on the outer peripheral surface of the shaft (51a). In this region, the brush portion (51b) is provided over the axial direction of the shaft (51a).

  The brush part (51b) is configured by planting brush hairs on a base substrate. Specifically, the brush part (51b) is formed 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. Moreover, this pile fabric is an inclined pile whose fur is inclined in a certain direction. In FIG. 8, the bristles of the brush part (51b) are inclined clockwise from the base substrate (to the adhesion preventing ridge part (51d) described later).

  When removing dust from the air filter (30), the air filter (30) is rotated in the direction of the arrow shown in FIG. Thus, while rotating the air filter (30), the bristles of the brush part (51b) are opposed to the moving direction of the contact portion of the air filter (30). Therefore, the dust adhering to the mesh member (37) can be scraped out efficiently.

  A positioning protrusion (51c) and an adhesion preventing protrusion (51d) extending in the axial direction are formed on the outer peripheral surface of the shaft (51a). These protrusions (51c, 51d) can determine the circumferential position of the brush part (51b) on the shaft (51a).

  The positioning protrusion (51c) removes dust from the air filter (30) with the brush part (51b) out of both ends in the circumferential direction (rotation direction) of the brush part (51b) of the rotating brush (51). In this state (the state shown in FIG. 8), the end portion on the side opposite to the cleaning brush (52) is positioned. The positioning protrusion (51c) is formed in a substantially rectangular cross section and has a height that allows positioning of the base fabric (thick line portion in the drawing) serving as the base of the brush portion (51b). Is formed.

  The adhesion preventing protrusion (51d) is configured to remove dust from the air filter (30) by the brush portion (51b) of both ends of the shaft portion (rotation direction) of the brush portion (51b) of the rotating brush (51). In the removed state (the state shown in FIG. 8), the end portion on the side close to the cleaning brush (52) (the end portion on the cleaning brush (52) side) is positioned. The adhesion preventing protrusion (51d) is provided so as to cover the end of the brush part (51b).

  The cleaning brush (52) removes dust adhering to the brush part (51b) in contact with the brush part (51b), and is provided along the axial direction of the rotating brush (51). The cleaning brush (52) is provided on one side of the rotating brush (51) so as to be able to contact the entire length of the brush portion (51b). The cleaning brush (52) includes a plate-like member (52a), a flocked portion (52b) disposed on the surface of the plate-like member (52a), and the plate-like member (52a) as a dust container (60). And a spring member (52c) elastically supported.

  The plate member (52a) is formed to have the same length as the shaft (51a) of the rotating brush (51). The front surface of the plate member (52a) is opposed to the outer peripheral surface of the rotating brush (51) with a predetermined interval. The upper part of the plate-like member (52a) is formed in an arc shape along the outer peripheral surface of the shaft (51a) of the rotating brush (51). The flocked portion (52b) is attached to the arc-shaped upper portion of the plate-like member (52a) over the length direction of the plate-like member (52a).

  The flocked portion (52b) of the cleaning brush (52) is composed of a pile fabric (inclined pile), like the brush portion (51b) of the rotating brush (51). The bristles of the flocked portion (52b) are inclined obliquely downward from the plate-like member (52a) in FIG. For this reason, when the rotating brush (51) rotates counterclockwise in FIG. 8, the bristles of the flocked portion (52b) oppose the rotating direction of the rotating brush (51), so the brush portion of the rotating brush (51) Dust adhering to (51b) is removed by the flocked portion (52b) of the cleaning brush (52).

  The brush part (51b) of the rotating brush (51) and the flocked part (52b) of the cleaning brush (52) are in contact with each other (the state shown in FIG. The hair is configured to extend toward the inner side of 60). Thereby, the dust adhering to the rotating brush (51) and the cleaning brush (52) can be efficiently collected in the dust container (60).

  Further, a protrusion (52d) protruding toward the rotating brush (51) is provided at the lower part of the plate-like member (52a). The protruding portion (52d) is provided below the flocked portion (52b). The protrusion (52d) is formed in a substantially triangular shape in cross-sectional view. The protrusion (52d) protrudes to the vicinity of the locus drawn by the protruding end of the adhesion preventing protrusion (51d) when the adhesion preventing protrusion (51d) of the rotating brush (51) passes. That is, the protrusion height of the protrusion (52d) is such that a minute gap is formed between the protrusion prevention protrusion (51d) and the attachment prevention protrusion (51d). Is set.

  The spring member (52c) is configured by a leaf spring. One end of the spring member (52c) is connected to the lower end of the plate-like member (52a), and the other end of the spring member (52c) is inside the second side surface (61c) of the dust container (60). Connected to the wall. The plate-like member (52a) has its lower end supported by a spring member (52c).

  As shown in FIG. 4, the rotating brush (51) and the cleaning brush (52) are each formed to have a length equal to or greater than the radius of the circular air filter (30). The rotating brush (51) and the cleaning brush (52) extend radially outward from the circle center of the air filter (30). That is, the dust removing mechanism (50) is arranged so as to extend in the radial direction of the air filter (30).

  As shown in FIGS. 6 and 7, the brush drive mechanism (53) includes a brush drive motor (54), and a drive gear (55) and a driven gear (56) that mesh 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). In the brush drive mechanism (53), the power of the brush drive motor (54) is transmitted to the rotary brush (51) via the drive gear (55) and the driven gear (56), and the rotary brush (51) is driven to rotate. .

  The brush drive mechanism (53) performs a brush cleaning operation for cleaning the brush portion (51b) of the rotating brush (51). In the brush cleaning operation, first, the brush drive mechanism (53) rotates the rotating brush (51) by a predetermined rotation angle clockwise in FIG. 8, and then rotates the rotating brush (51) counterclockwise in FIG. Rotate. The dust adhering to the brush portion (51b) of the rotating brush (51) adheres to the flocked portion (52b) of the cleaning brush (52) when the rotating brush (51) rotates counterclockwise in FIG. . Subsequently, the brush drive mechanism (53) again rotates the rotating brush (51) clockwise in FIG. At that time, the dust adhering to the flocked portion (52b) of the cleaning brush (52) is scraped off by the brush portion (51b) of the rotating brush (51) and is stored in the storage portion (62) of the dust storage container (60). Fall. In the brush cleaning operation, the rotation brush (51) is driven to rotate in both directions around the rotation axis by changing the rotation direction of the brush drive motor (54). Details of the brush cleaning operation will be described later.

  By the way, at the time of the “brush cleaning operation”, the dust is the end of the brush portion (51b) of the rotating brush (51) (the end in the traveling direction when the rotating brush (51) rotates clockwise in FIG. 8). ) May adhere. When the “brush cleaning operation” is performed a plurality of times, dust is continuously formed in a band shape at the end. Then, as shown in FIG. 13 (d), the dust adhering to the end of the brush portion (51b) is separated from the surface of the rotating brush (51) by the protrusion preventing protrusion (51d). It will extend to. Therefore, the adhesion preventing protrusion (51d) can prevent dust from being entangled with the shaft (51a) or becoming difficult to remove from the rotating brush (51).

  The dust container (60) is a container for temporarily storing dust removed from the air filter (30) by the rotating brush (51). Dust removed from the rotating brush (51) by the cleaning brush (52) is stored in the dust container (60). As shown in FIG. 6, the dust container (60) is formed in a columnar shape as a whole. The dust container (60) is provided in a state where its longitudinal direction is horizontal. The rotating brush (51) is accommodated in the accommodating space (59) of the dust container (60). An opening (63) for exposing the brush portion (51b) of the rotating brush (51) to the outside of the dust storage container (60) is formed on the upper surface of the dust storage container (60).

  Specifically, as shown in FIG. 8, when the dust container (60) is viewed in a cross section (transverse section) perpendicular to the longitudinal direction, the upper part of the dust container (60) removes dust. The removal part (61) which accommodates the rotating brush (51) for this comprises, and the lower part of the dust storage container (60) comprises the storage part (62) for storing dust. The storage part (62) is disposed obliquely below the vertical direction of the rotating brush (51). Specifically, the storage part (62) swells in an arc shape from the lower end of the removal part (61) to the side (left side in FIG. 8), and the storage space (58) and the accommodation space (59) communicate with each other. ing.

  The removal portion (61) is formed in a substantially rectangular parallelepiped box shape having an open lower end. The removal part (61) extends in the longitudinal direction of the dust container (60). The space in the removal part (61) constitutes an accommodation space (59) for accommodating the rotating brush (51). Further, as shown in FIGS. 6 and 8, the upper surface portion (61a) and the first side surface portion (61b) and the second side surface extending downward from both ends in the short direction (width direction) of the upper surface portion (61a), respectively. A portion (61c), and a first end surface portion (61d) and a second end surface portion (61e) respectively extending downward from both ends in the longitudinal direction of the upper surface portion (61a).

  In the removal part (61), the side part on the side where the storage part (62) bulges (the left side in FIG. 8) constitutes the first side part (61b), and the first side face across the rotating brush (51). The side part located on the opposite side of the part (61b) constitutes the second side part (61c). The height of the first side surface portion (61b) is higher than that of the second side surface portion (61c).

  In the upper surface portion (61a), the above-described opening (63) is formed. The opening (63) is formed in a rectangular shape. The opening (63) extends in the longitudinal direction of the removal portion (61). A rotating brush (51) is disposed in the opening (63). The axial direction of the shaft (51a) coincides with the longitudinal direction of the opening (63). The rotating brush (51) is provided such that the flocked portion (52b) can be exposed to the outside of the opening (63). Both ends of the shaft (51a) are supported by the first end surface portion (61d) and the second end surface portion (61e) of the removal portion (61), respectively.

  In addition to the rotating brush (51), the above-described cleaning brush (52) is also accommodated in the removing section (61). The cleaning brush (52) is disposed on the opposite side of the storage space (58) across the rotating brush (51) in the accommodation space (59). More specifically, it is disposed between the outer peripheral surface of the shaft (51a) and the inner wall surface of the second side surface portion (61c). By arranging the cleaning brush (52) in this way, even if the dust removed from the air filter (30) by the rotating brush (51) becomes a band during the brush cleaning operation, the band-like dust is stored. It can be reliably guided to the space (58) side.

  Specifically, when the cleaning brush (52) is arranged on the side close to the storage space (58) (between the outer peripheral surface of the shaft (51a) and the inner wall surface of the first side surface portion (61b)), it rotates. While the brush (51) is rotationally driven in both directions around the rotation axis, the belt-like dust is bent toward the rotary brush (51). For this reason, when the belt-like dust reaches the inner surface of the accommodation space (59), it is guided to the space on the opposite side to the storage space (58). When the belt-like dust comes off the rotating brush (51), it may remain in the space opposite to the storage space (58).

  On the other hand, in the present invention, the cleaning brush (52) is disposed on the opposite side of the storage space (58) with the rotary brush (51) interposed therebetween, so that the belt-like dust is placed on the rotary brush (51) side. When it becomes a bent shape and reaches the inner surface of the accommodation space (59), the tip of the belt-like dust comes to face the storage space (58). As a result, when the belt-like dust is removed from the rotating brush (51), the dust can be reliably guided to the storage space (58), and the dust can be prevented from remaining in the accommodation space (59). .

  The upper end portion of the plate-like member (52a) of the cleaning brush (52) is located in the opening (63). When the rotary brush (51) side is the front side in the cleaning brush (52), the opening (63) allows the movement of the upper end of the plate-like member (52a) to the front and rear.

  As shown in FIG. 8, the storage part (62) includes a substantially C-shaped bulging part (62a) and a plate-like slope part (62b) in a cross-sectional view. The upper end portion of the bulging portion (62a) is connected to the lower end of the first side surface portion (61b). The outer surface on one side of the dust container (60) has a bulging portion (62a) that bulges outward in an arc shape, with the boundary between the first side surface portion (61b) and the bulging portion (62a) as the break point. Yes. On the other hand, the lower end portion of the bulging portion (62a) is connected to the lower end of the slope portion (62b) located below the rotating brush (51). The upper end of the slope portion (62b) is connected to the lower end of the second side surface portion (61c). The outer side surface on the other side of the dust container (60) is bent in a “<” shape with the boundary between the second side surface portion (61c) and the slope portion (62b) as a break point.

  In the dust container (60), the dust removed from the rotating brush (51) falls on the slope part (62b) and is guided to the bulging part (62a) by the slope of the slope part (62b). In the dust container (60), much of the dust removed from the rotating brush (51) is stored in the bulging portion (62a). The space in the bulging portion (62a) constitutes a storage space (58) in which dust is stored.

  Moreover, as shown in FIG. 6, the length of the slope part (62b) is equal to the length of the removal part (61) in the longitudinal direction. The length of the bulging part (62a) is longer than the length of the removal part (61) in the longitudinal direction. The bulging portion (62a) has a first end portion (66) and a second end portion (67) opened at both ends in the longitudinal direction. A damper box (81) described later is connected to the first end (66) of the bulging portion (62a), and a transfer duct (88) described later is connected to the second end (67). Yes.

  As shown in FIG. 8, a first seal member (45) and a second seal member (46) are provided in the dust container (60). Both the first seal member (45) and the second seal member (46) are arranged so as to partition the storage space (58) and the opening (63) in the dust storage container (60). 60) is attached to the inner surface. Both the first seal member (45) and the second seal member (46) extend from the inner wall surface of the first end surface portion (61d) of the removal portion (61) to the inner wall surface of the second end surface portion (61e). . That is, the first seal member (45) and the second seal member (46) partition the storage space (58) and the opening (63) over the longitudinal direction of the dust storage container (60). This prevents dust in the dust container (60) from flowing out of the opening (63).

  The first seal member (45) is a member for closing a gap between the inner wall surface of the first side surface portion (61b) and the outer peripheral surface of the rotary brush (51). As shown in FIG. 8, the first seal member (45) is provided on the inner wall surface of the first side surface portion (61b). The first seal member (45) is provided on the inner wall surface of the dust container (60) opposite to the cleaning brush (52) with the rotating brush (51) interposed therebetween. The first seal member (45) extends from the inner wall surface of the dust container (60) toward the outer peripheral surface of the rotating brush (51).

  The second seal member (46) is a member for closing a gap between the inner wall surface of the second side surface portion (61c) and the cleaning brush (52). Here, a gap (57) is formed between the edge of the opening (63) and the back of the upper end of the plate-like member (52a) of the cleaning brush (52), as shown in FIG. ing. In the present embodiment, the second seal member (46) is provided to prevent the dust from flowing out of the dust container (60) through the gap (57).

  Moreover, the filter attachment part (68) mentioned above is provided in the upper end of the outer surface of the 1st end surface part (61d) of the said removal part (61). The filter mounting portion (68) is formed to protrude in a substantially U shape in plan view so as to open on the side opposite to the storage portion (62) side.

  Further, as shown in FIG. 8, the dust storage container (60) is provided with a storage amount detection mechanism (70) for detecting the amount of dust stored in the storage portion (62). The storage amount detection mechanism (70) includes a light emitting LED (72) and a phototransistor (73) housed in a sensor box (71). The sensor box (71) is provided near the second end (67) of the storage part (62) of the dust storage container (60) so as to extend in the transverse direction of the storage part (62) and cover the bottom thereof. Yes. The light emitting LED (72) and the phototransistor (73) are opposed to each other in the sensor box (71) 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 surface of the storage part (62), corresponding to the light emitting LED (72) and the phototransistor (73), respectively.

  With the above configuration, in the storage amount detection mechanism (70), light generated by the light emitting LED (72) sequentially passes through the first transparent window (64) and the second transparent window (65), and then the phototransistor ( 73) the light intensity is detected. Depending on the light intensity detected by the phototransistor (73), the amount of dust stored in the storage part (62) (that is, the degree of filling) can be detected.

  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 is detected by the phototransistor (73). Brightness 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) becomes low and is detected by the phototransistor (73). The luminous intensity is low.

  Therefore, according to the storage amount detection mechanism (70), for example, when the light intensity becomes a predetermined value or less, it can be determined that the storage amount of the storage unit (62) is large. Thereby, even after a dust transfer operation for transferring dust in the storage section (62) by a dust transfer mechanism (80) described later, the storage of the dust in the storage section (62) is performed by the storage amount detection mechanism (70). When it is detected that the amount is large, it is possible to determine that the inside of the dust collection box (90) that is the destination of the dust is full.

  The dust transfer mechanism (80) includes the above-described damper box (81) and transfer duct (88), an introduction duct (86), and a suction duct (87).

  The damper box (81) is formed in a rectangular parallelepiped shape, and one end side in the longitudinal direction thereof is connected to the first end portion (66) of the storage portion (62). As shown in FIGS. 9 and 10, the damper box (81) is provided with a damper (82) that is an opening / closing member. When the damper (82) is closed, the internal space of the damper box (81) is partitioned in the longitudinal direction. That is, the internal space of the damper box (81) is partitioned by the damper (82) into a first chamber (81a) on the other end side and a second chamber (81b) on the dust storage container (60) side on one end side. Is done. As described above, the first end (66) of the reservoir (62) is connected to the second chamber (81b) that is defined on one end of the damper box (81), and the second chamber (81b) 81b) and the reservoir (62) communicate with each other.

  As shown in FIGS. 7 and 10, the dust transfer mechanism (80) includes a damper drive motor (83), a drive gear (84), and a driven gear (85) for opening and closing the damper (82). ing. The drive gear (84) is connected to the drive shaft of the damper drive motor (83), and the driven gear (85) is connected to the rotating shaft of the damper (82). The drive gear (84) and the driven gear (85) are arranged so as to mesh with each other. With this configuration, the power of the damper drive motor (83) is transmitted to the rotating shaft of the damper (82) via each gear (84, 85). Thus, an opening / closing operation is performed in which the damper (82) rotates about the rotation axis by the rotation of the damper drive motor (83).

  As shown in FIG. 9, the one end side of the introduction duct (86) is connected to the upper surface of the damper box (81) and communicates with the first chamber (81a) in the damper box (81). . On the other hand, the other end side of the introduction duct (86) extends vertically upward from the damper box (81) and includes a partition plate (25) provided between the cleaning unit (100) and the main unit (10). It penetrates and is connected to the extension part of the drain pan (23) of the main unit (10). The introduction duct (86) includes an upstream duct (86a) and a downstream duct (86b) having a circular cross section, and these two members (86a, 86b) are secured by a set screw (86c). It is connected in the vertical direction.

  The upstream duct (86a) is formed such that its cross-sectional area (flow path area) is larger than the cross-sectional area (flow path area) of the downstream duct (86b). The lower end (lower side in FIG. 9) of the downstream duct (86b) is connected to the upper surface of the damper box (81). On the other hand, the upper end (upper side in FIG. 9) of the upstream duct (86a) is in contact with the horizontally extending extension portion of the drain pan (23) via the seal member (86e). In the extended portion of the drain pan (23), an introduction port (86d) which is a through hole is formed. The upstream duct (86a) communicates with the space on the indoor fan (21) side through the introduction port (86d). That is, the introduction duct (86) is configured to introduce the air blown from the indoor fan (21) into the damper box (81).

  In addition, in the introduction duct (86), a connecting portion between the upstream duct (86a) and the downstream duct (86b) is located in the penetrating portion of the partition plate (25). Specifically, both the ducts (86a, 86b) are connected so that the through hole periphery of the partition plate (25) is sandwiched between the bottom plate of the upstream duct (86a) and the upper end flange of the downstream duct (86b). Yes. With this configuration, it is possible to connect the upper end of the introduction duct (86) to the bell mouth (24) while sandwiching the periphery of the through hole of the partition plate (25) so that the introduction duct (86) does not fall off. .

  Furthermore, as described above, the upstream duct is configured by sandwiching the periphery of the through hole of the partition plate (25) between the bottom plate of the upstream duct (86a) and the upper end flange of the downstream duct (86b). The connecting portion between (86a) and the downstream duct (86b) can be rotated with respect to the partition plate (25). Moreover, in this embodiment, the contact portion between the upstream duct (86a) and the seal member (86e) is also configured to be rotatable, so that the introduction duct (86), the damper box (81), and the dust removal The mechanism (50) can rotate integrally around the axis (introduction port) of the introduction duct (86).

  As shown in FIGS. 6 and 7, the suction duct (87) has one end on the inflow side connected to the lower surface of the damper box (81). The suction duct (87) communicates with the second chamber (81b) in the damper box (81). On the other hand, the other end on the outflow side of the suction duct (87) is connected to a nozzle insertion portion (110) formed on the decorative panel (11). Although not particularly shown, the nozzle insertion portion (110) has an opening for inserting and suctioning a nozzle of a cleaner.

  As shown in FIGS. 2 and 4, the transfer duct (88) has one end connected to the second end (67) of the storage part (62) in the dust storage container (60) and the other end connected to a dust trap. Connected to the collection box (90). That is, the transfer duct (88) communicates the dust container (60) with the dust collection box (90). The transport duct (88) is formed of a flexible tube.

  In the dust transfer mechanism (80) having the above-described configuration, the damper (82) of the damper box (81) is closed during normal operation in which air conditioning is performed (see FIG. 10 (a)). Thereby, the air blown from the indoor fan (21) is not introduced into the second chamber (81b) of the damper box (81). On the other hand, when the dust in the dust container (60) is transported to the dust collection box (90), the damper (82) of the damper box (81) is opened (see FIG. 10B). Thereby, the air blown from the indoor fan (21) is introduced into the dust container (60) through the introduction duct (86) and the damper box (81). As a result, the dust in the dust container (60) flows along with the introduced air through the transfer duct (88) and is transferred into the dust collection box (90). That is, by opening the damper (82) in the damper box (81), the dust in the dust container (60) is transferred to the dust collection box (90) using the air blown from the indoor fan (21). be able to.

  Further, in the dust transport mechanism (80), the damper (82) of the damper box (81) is closed even when the dust collected in the dust collection box (90) is discharged out of the casing (101). (See FIG. 10C). In this case, the dust in the dust collection box (90) is sucked from the nozzle insertion portion (110) by a vacuum cleaner, so that the dust in the transport duct (88), the damper box (81), and the suction duct (87) Through the vacuum cleaner.

  The dust collection box (90) is for storing the dust transferred from the dust storage container (60). As shown in FIG. 4, the dust collection box (90) is formed in a slightly elongated and substantially rectangular parallelepiped shape, and is disposed below the partition plate (25), similarly to the dust container (60). The dust collection box (90) is disposed on the side of the air filter (30) and along one end side of the partition plate (25) so as not to overlap the air filter (30) in plan view. . In addition, the dust collection box (90) has an arc-shaped side plate on the air filter (30) side corresponding to the outer periphery of the air filter (30) in order to prevent interference with the air filter (30). Is formed.

  The dust collection box (90) has an inlet (94) formed on the side surface of one end (one side). The other end of the transfer duct (88) is connected to the inflow port (94). On the other hand, the other end (other side) of the dust collection box (90) is provided with an exhaust port (91) that opens into the casing (101) of the cleaning unit (100). That is, the dust collection box (90) is provided with an exhaust port (91) at the end opposite to the side to which the transfer duct (88) is connected, and the inside of the dust collection box (90) has a longitudinal direction. It is easy to flow. The dust collection box (90) has a smaller cross-sectional area at the exhaust port (91) side than at the other parts.

  In the dust collection box (90), a filter (92) is provided near the exhaust port (91). By providing this filter (92), when dust is transported from the dust container (60) into the dust collection box (90), air is exhausted from the exhaust port (91), while the transported dust is Is captured by the filter (92) and does not flow out of the exhaust port (91). In addition, when dust is discharged from the dust collection box (90) by suction with a vacuum cleaner, room air flows into the dust collection box (90) through the exhaust port (91). The dust is trapped by the filter (92). Thus, since the pressure balance in the dust collection box (90) becomes appropriate by the air supply / exhaust through the exhaust port (91), the dust transport operation and the discharge operation are appropriately performed with respect to the dust collection box (90). .

-Driving action-
Next, the operation of the indoor unit (3) will be described. The indoor unit (3) is configured to be switchable between a normal operation for performing cooling and heating and a filter cleaning operation for cleaning the air filter (30).

<Normal operation>
In normal operation, the damper (82) of the damper box (81) is closed (the state shown in FIG. 10 (a)). The air filter (30) is set to a non-rotating stop state.

  In this state, the indoor fan (21) is driven. Then, in the indoor unit (3), 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 operation, as shown in FIG. 10A, the damper (82) of the damper box (81) is closed, so that the air blown from the indoor fan (21) is passed through the damper box (81) to the dust container ( 60) will not be introduced.

<Filter cleaning operation>
In the filter cleaning operation, the compressor (4) is stopped in the refrigerant circuit shown in FIG. 1, and the refrigerant does not circulate. In this filter cleaning operation, “dust removal operation”, “brush cleaning operation”, “dust transport operation”, and “dust discharge operation” are switchable.

  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 trapped on 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 indoor unit (3). In the present embodiment, “dust removal operation” and “brush cleaning operation” are performed alternately.

−Dust removal operation−
First, in the “dust removal operation”, the indoor fan (21) is operated so as to blow out a weak wind. Then, with the brush part (51b) of the rotating brush (51) in contact with the air filter (30), the air filter (30) is turned upside down on the hair of the brush part (51b) of the rotating brush (51). (A white arrow direction in FIGS. 11B and 12A). At this time, the rotating brush (51) is in a stopped state.

  Then, the dust of the air filter (30) is captured by the brush portion (51b) of the rotating brush (51) (FIG. 12 (b)). Here, for example, as shown in FIG. 12 (a), the bristles of the brush portion (51b) of the rotating brush (51) are inclined in the direction opposite to the rotation direction of the air filter (30). The dust of (30) is easily scraped off by the brush part (51b). When the limit switch is activated, the filter drive motor (40) stops and the rotation of the air filter (30) stops. That is, the air filter (30) rotates by a predetermined angle and stops. Therefore, the dust in the area | region which contacted the brush part (51b) of the rotating brush (51) in an air filter (30) is removed.

−Brush cleaning operation−
When the rotation of the air filter (30) stops, the “dust removal operation” is switched to the “brush cleaning operation”.

  By the way, after the rotation of the air filter (30) is stopped, as shown in FIG. 12B, dust is left on the left side of the brush part (51b) of the rotating brush (51) (that is, in front of the rotating direction of the air filter (30) Side). This is because the dust scraped off by the brush part (51b) is dragged along with the movement of the air filter (30). Therefore, if it remains as it is, the lump of dust becomes large, and there is a possibility that it will eventually fall into the room or the like.

  Therefore, in the “brush cleaning operation”, first, as shown in FIG. 11C, the air filter (30) is rotated by the filter drive motor (40) to return it by a desired angle counterclockwise. That is, as shown in FIG. 13A, the air filter (30) has a direction opposite to that in the “dust removal operation”, that is, a direction in which the hair of the brush portion (51b) of the rotating brush (51) extends. Rotate in the same direction. In the present embodiment, the air filter (30) is rotated so as to move by an angle corresponding to the width of the brush portion (51b) of the rotating brush (51).

  Then, as shown in FIG. 13A, if the dust that is biased to one side of the brush portion (51b) of the rotating brush (51) is spread over a wide range of the brush portion (51b) by the air filter (30). Is done. That is, dust adheres more uniformly over a wide range of the brush portion (51b). Thereby, since dust adheres reliably by a brush part (51b), it can prevent more reliably that the lump of dust falls into a room | chamber interior.

  Subsequently, in the “brush cleaning operation”, the rotating brush (51) rotates clockwise (clockwise) in FIG. 13 with the air filter (30) stopped. At that time, the rotating brush (51) rotates so that the brush portion (51b) contacts the flocked portion (52b) of the cleaning brush (52) while dust is captured by the brush portion (51b) (FIG. 13). (B)). The rotating brush (51) stops after rotating by a predetermined rotation angle.

  Thereafter, the rotating brush (51) rotates counterclockwise (counterclockwise in FIG. 13 (counterclockwise) in FIG. 13). Then, the dust captured by the brush part (51b) of the rotating brush (51) is captured by the flocked part (52b) of the cleaning brush (52) (FIG. 13 (c)). This is because the hair of the flocked portion (52b) of the cleaning brush (52) is planted so that the bristles face downward, that is, stand upside down by the counterclockwise rotation of the rotating brush (51). This is because the dust adhering to the brush part (51b) of the rotating brush (51) is scraped off.

  When the brush portion (51b) of the rotating brush (51) and the flocked portion (52b) of the cleaning brush (52) are in contact with each other, the plate-like member (52a) of the cleaning brush (52) is turned into the rotating brush (51 ), But the plate-like member (52a) is biased toward the rotating brush (51) by the spring member (52c), so that the brush parts (51b, 52b) are separated from each other. The cleaning brush (52) is properly pressed against the rotating brush (51). Therefore, dust can be more reliably removed from the brush portion (51b) of the rotating brush (51), and the dust can be trapped in the flocked portion (52b) of the cleaning brush (52). The rotating brush (51) rotates to the original state (state shown in FIG. 13A) and stops.

  Subsequently, the rotating brush (51) rotates again by a predetermined rotation angle clockwise (clockwise) again. Then, the dust trapped on the flocked portion (52b) of the cleaning brush (52) is scraped off by the brush portion (51b) of the rotating brush (51) (FIG. 13 (d)). That is, since the bristles of the brush part (51b) of the rotating brush (51) are inclined downward along the rotational direction, dust is scraped off from the flocked part (52b) of the cleaning brush (52). be able to. At this time, the cleaning brush (52) is appropriately pressed against the rotating brush (51) by the spring member (52c), so that dust can be more reliably removed from the cleaning brush (52).

  Thus, the dust trapped on the rotating brush (51) is removed and stored in the storage part (62) of the dust storage container (60). Thereafter, the rotating brush (51) rotates again counterclockwise (counterclockwise) to return to the original state (FIG. 9 (a)), and the “brush cleaning operation” is temporarily ended.

  In the “brush cleaning operation”, the rotating brush (51) is driven to rotate so that the brush part (51b) reciprocates only in a part of the brush passage area along the entire circumference of the outer peripheral surface of the shaft (51a). Is done. That is, the brush part (51b) passes only through the brush passage area which is a partial area around the rotation axis of the rotary brush (51). In the region along the entire circumference of the outer peripheral surface of the shaft (51a), there are a brush passing region and an exposed region in which only the portion where the outer peripheral surface of the shaft (51a) is exposed without passing the brush portion (51b) passes. It is formed.

  When the “brush cleaning operation” as described above is completed, the “dust removal operation” described above is performed again. That is, the air filter (30) is rotated again, and the air filter (30) stops when the limit switch is actuated again. Thereby, the dust of the area | region which passed the brush part (51b) of the rotating brush (51) in an air filter (30) is capture | acquired by the brush part (51b) of a rotating brush (51). In this way, by alternately repeating the “dust removal operation” and the “brush cleaning operation”, dust is removed for each predetermined region of the air filter (30). When dust is removed from the entire area of the air filter (30), the “dust removal operation” and the “brush cleaning operation” are completely completed. For example, when the limit switch is actuated a predetermined number of times, it is determined that the air filter (30) has made one rotation, and the operation ends.

−Dust transfer operation−
During the “dust removal operation” and “brush cleaning operation” described above, the storage amount detection mechanism (70) detects the dust storage amount in the dust storage container (60). That is, the light intensity of the light emitted from the light emitting LED (72) is detected by the phototransistor (73). Then, when the detected light intensity of the phototransistor (73) becomes equal to or less than the set value (lower limit value), the amount of dust in the dust container (60) has reached a predetermined amount, and the operation is switched to “dust transfer operation”.

  In the “dust transfer operation”, the rotary brush (51) is stopped in the state shown in FIG. 8, and the air filter (30) is stopped. Further, the damper (82) of the damper box (81) is in the open state (the state shown in FIG. 10B). In this state, when the indoor fan (21) is driven, the air blown from the indoor fan (21) is introduced into the dust container (60) through the introduction duct (86) and the damper box (81). Is done. Thereby, the dust in the dust container (60) is transferred into the dust collection box (90) through the transfer duct (88) together with the air. As a result, the amount of dust stored in the dust container (60) decreases, and the light intensity detected by the phototransistor (73) increases. Then, when the detected light intensity is equal to or greater than a set value (upper limit value), the “dust transporting operation” is terminated, assuming that most of the dust in the dust container (60) has been discharged. Thereafter, the “dust removal operation” or “brush cleaning operation” is resumed.

−Dust discharge operation−
In the filter cleaning operation of the present embodiment, a “dust discharge operation” is performed according to a predetermined condition. That is, after opening the damper (82) in the “dust transfer operation”, the light emitting LED (72) is turned on to detect the light intensity, and if the light intensity is lower than a predetermined value, the dust storage container (60) Dust is not conveyed by the air blown from the indoor fan (21), that is, the dust is clogged in the conveyance path from the dust container (60) to the dust collection box (90), or the dust collection box (90 ), It is determined that a large amount of dust has been collected, and the user is notified of this, and the following “dust discharge operation” is performed in accordance with remote control operation or the like.

  In the “dust discharging operation”, the rotary brush (51) is stopped in the state of FIG. 8 and the air filter (30) is stopped as in the “dust transporting operation” described above. Further, the damper (82) of the damper box (81) is in the closed state (the state shown in FIG. 10C).

  In the state described above, the suction operation is performed in a state where the nozzle of the vacuum cleaner is inserted into the nozzle insertion portion (110) of the decorative panel (11) by the user. By this suction operation, the dust in the dust collection box (90) is moved into the transport duct (88), the dust container (60), the damper box (81), the suction duct (87) and the nozzle insertion part (110). Is sucked into the vacuum cleaner. At that time, the dust remaining in the dust container (60) is also sucked into the cleaner through the suction duct (87). As a result, the dust in the dust collection box (90) and the dust container (60) is discharged out of the indoor unit (3).

-Effect of the embodiment-
According to the present invention, since the cleaning brush (52) is arranged on the opposite side of the storage space (58) with the rotating brush (51) in between, the belt-like dust is bent toward the rotating brush (51). When the shape reaches the inner surface of the accommodation space (59), the tip of the belt-like dust comes to face the storage space (58). As a result, when the belt-like dust is removed from the rotating brush (51), the dust can be reliably guided to the storage space (58), and the dust can be prevented from remaining in the accommodation space (59). .

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

  In the embodiment, the dust removed from the air filter (30) is collected in the dust collection box (90). However, the present invention is not limited to this. For example, if the configuration can collect dust, Any configuration such as a bag shape may be used.

  In the above embodiment, the dust collection box (90) is provided in the cleaning unit (100). However, the present invention is not limited to this, and the dust collection box (90) may be provided separately from the indoor unit (3).

  In the above embodiment, the air blown from the indoor fan (21) is used as means for conveying dust from the dust container (60) to the dust collection box (90). Any configuration may be used as long as dust can be conveyed, and a dedicated fan may be provided.

  Moreover, in the said embodiment, although the air filter (30) is formed in circular shape, it is not restricted to this, For example, you may form in rectangular shape. In this case, the air filter (30) and the rotating brush (51) move relatively linearly.

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

1 Air conditioner
3 Indoor unit
21 Indoor fan
30 Air filter
51 Rotating brush
51b Brush part
52 Cleaning brush
58 Storage space
59 containment space
60 Dust storage container

Claims (2)

Indoor fan (21), air filter (30) for capturing dust in the air sucked into the indoor fan (21), and brush part (51b) for removing dust adhering to the air filter (30) An air conditioner indoor unit comprising a rotating brush (51) having a dust storage container (60) for storing dust removed from the air filter (30) by the rotating brush (51),
A cleaning brush (52) for removing dust adhering to the surface of the brush part (51b) by contacting the brush part (51b) when the rotating brush (51) rotates;
The dust container (60) communicates with the housing space (59) at a position obliquely below the housing space (59) for housing the rotating brush (51) and the vertical direction of the rotating brush (51). A storage space (58) for storing the dust removed by the rotating brush (51).
The cleaning brush (52) is disposed on the opposite side of the storage space (58) across the rotating brush (51) in the housing space (59). Indoor unit. In claim 1,
The rotating brush (51) performs a brush cleaning operation in which the brush portion (51b) is reciprocated in the rotation direction in order to remove dust adhering to the brush portion (51b) by the cleaning brush (52). An indoor unit of an air conditioner characterized by being configured as described above.

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