JP4878521B2 - Air conditioner indoor unit - Google Patents

Description

  The present invention relates to an indoor unit of an air conditioner capable of a sterilization operation in which at least the inside of a main body is sterilized with ozone as an in-machine clean operation function.

A blower is accommodated in the indoor unit main body together with an air filter and a heat exchanger. This blower sucks room air, distributes it to the heat exchanger, exchanges heat, and then blows out again into the room. A blower employed in an indoor unit is composed of a cross flow fan and a motor that rotationally drives the cross flow fan.
The crossflow fan constituting the blower is not captured by the air filter, and fine dust and mold spores contained in the air that has passed through the air filter are likely to adhere to the crossflow fan. Long-term use may cause dust and mold to adhere to and accumulate on the surface of the cross-flow fan, resulting in a decrease in air conditioning capability and an increase in power consumption.
Therefore, in recent years, drying operation to remove moisture in the main body that causes mold generation, sterilization operation to fill the inside with ozone to kill mold spores, and exhausting dirty air and moisture inside the main body to the outside An air conditioner that can perform in-machine clean operation such as exhaust operation is disclosed in [Patent Document 1].
JP 2002-349891 A

If the technique of [Patent Document 1] is adopted, in-machine cleaning becomes unnecessary for a long period of time. In-machine clean operation, especially sterilization operation, is performed by closing the inlet and outlet and then stopping the blower and energizing the electrostatic precipitator, which is an ozone generator. Let it sterilize with ozone.
Actually, in order to suppress the outflow of ozone to the outside of the machine and enhance the ozone sterilization effect in the machine, the ozone generator is activated with the cross-flow fan in the machine stopped, and the ozone is filled in the machine. . For this reason, it took time for ozone to reach every corner of the aircraft.

Further, the in-machine clean operation for performing ozone sterilization is set to be automatically executed after stopping the normal air-conditioning operation. That is, after stopping the stop button, the operation state is further continued for a predetermined long time (around one hour). For this reason, some users may misunderstand that the in-flight clean operation continues without stopping the air conditioning operation, and may forcibly stop the operation during the clean operation.
If the air conditioner is used for a long period of time while the in-machine clean operation is not sufficiently performed, the sterilization in the main body becomes insufficient. In particular, the sterilization of the cross-flow fan arranged on the downstream side of the heat exchanger becomes insufficient, and depending on the use conditions, mold spores adhering to the fan surface propagate and accumulate as fine dust adheres, This causes a decrease in the blowing efficiency.

  The present invention has been made based on the above circumstances, the purpose of which is to circulate ozone air in the indoor unit body by forming a forced circulation path of ozone air that operated a cross-flow fan during in-machine clean operation, Air-conditioning capability at the time of installation by improving the usability of the air conditioner by obtaining the sterilizing effect in the machine in a short time and shortening the overall clean operation time, and keeping the interior clean for a long period of time It aims to provide an indoor unit of an air conditioner that can hold the air.

In order to satisfy the above object, the indoor unit of the air conditioner of the present invention has a blower on the air secondary side of the air filter, the heat exchanger, and the heat exchanger in the air passage that communicates the air inlet and outlet of the indoor unit body. Are arranged in order, and are provided with an ozone generator that is controlled in operation during the sterilization operation in the indoor unit body and an exhaust device that discharges the secondary air of the heat exchanger to the outside, The cross flow fan is provided with a casing from the periphery to the blowout port, and is opposed to the casing over the entire length in the axial direction of the cross flow fan, and is formed in a flat plate shape, and one end thereof is supported by the casing via a rotation fulcrum. An airflow change device comprising an airflow change plate and a drive unit that rotationally biases the airflow change plate,
The airflow changing plate has a pivot fulcrum provided on the downstream side of the air passage, a free end is directed to the upstream side of the air passage, and is housed in a casing that forms the air passage when not in operation, None, during the sterilization operation in the machine, it is projected into the air passage by the drive unit, the tip is close to the outer periphery of the cross flow fan so as to act as a pseudo nose , and the cross flow into the indoor unit body as the blower operates The airflow generated by the rotation of the fan is guided to the exhaust device by forming a circulating flow that forcibly circulates the crossflow fan and the secondary side of the heat exchanger around it .

  According to the present invention, the time required for in-flight clean operation can be shortened, and therefore, the interior can be kept clean for a long period of time, and the air conditioning capability at the time of installation can be maintained.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a schematic longitudinal sectional view of an indoor unit of an air conditioner, and FIG. 2 is a front view of the indoor unit body 1 with the front panel 2 removed. (Note that parts not marked in the description are not shown. The same applies hereinafter.)
The indoor unit main body 1 is composed of a front panel 2 and a rear plate casing 3 that constitute a front casing, and is horizontally long in the width direction with respect to the vertical direction. A front suction port 4 is opened at a part of the front side of the indoor unit main body 1, and a movable panel 2 </ b> A supported by an opening / closing drive mechanism is fitted into the front panel 2 facing the front suction port 4.

When the air-conditioning operation is stopped as shown in FIG. 1 (during the in-machine clean operation described later), the movable panel 2A is joined to the surface of the front panel 2 to close the front inlet 4. During the air conditioning operation, the front suction port 4 is controlled so as to protrude to the front side and open to the room. An upper suction port 5 that is partitioned into a plurality of spaces by a crosspiece is provided in the upper part of the indoor unit main body 1.
A blower outlet 6 is opened at the front lower portion of the indoor unit body 1, and two blowout louvers 7a and 7b are provided in parallel at the blower outlet 6. Each blowing louver 7a, 7b takes a turning posture according to the type of air conditioning operation, and the blowing direction of the heat exchange air is set. The air outlet 6 is closed when the air conditioning operation is stopped (during the in-flight clean operation).

In the indoor unit main body 1, a heat exchanger 8 formed in a substantially inverted V shape by the front heat exchanger portion 8A and the rear heat exchanger portion 8B is disposed. The front heat exchanger portion 8A is formed in a substantially parallel curved shape with a gap with the front panel 2, and faces the front suction port 4 and part of the upper suction port 5. The rear heat exchanger portion 8B is formed in a straight shape, and is inclined obliquely and opposed to a part of the upper suction port 5.
A frame assembly 10 is provided between the front panel 2 and the heat exchanger 8. A front air filter 11A and an upper air filter 11B constituting the air filter 11 are interposed between the front suction port 4 and the upper suction port 5, and the front heat exchanger portion 8A and the rear heat exchanger portion 8B. , Each is supported movably with respect to the frame assembly 10.

The air filter cleaning device A is disposed between the upper end of the front air filter 11A and the front end of the upper air filter 11B in the frame assembly 10. The air filter cleaning apparatus A includes a drive unit that reciprocates the front air filter 11A toward the upper surface side of the upper air filter 11B and reciprocates the upper air filter 11B toward the front surface side of the front air filter 11A.
Further, the air filter cleaning device A collects in the dust box 12 a roll brush 13 for removing dust that adheres to and accumulates on each air filter during the movement of the front air filter 11A and the upper air filter 11B, and the removed dust. A dust receiving passage 14 and a sealing mechanism 15 that closes the dust box 12 so as to prevent the removed dust from scattering from the air filter cleaning device A to the periphery are provided.

An air cleaning unit 17 is attached to the frame assembly 10 so as to be positioned on the front side of the front heat exchanger 8A and on the back side of the front air filter 11A. The air cleaning unit 17 includes a pair of left and right electric dust collectors 18 and 18 and a dust collector power supply unit 19 disposed on the side of one of the electric dust collectors 18.
Each electrostatic precipitator 18 includes a charge side electrode that applies a charge to the dust in the flowing air, and a dust collection side electrode that captures the charged dust. Each electrode surface is coated with a deodorizing agent, and has both a dust collecting function and a deodorizing function as an electric dust collector. The electric dust collector 18 is also an ozone generator having a function of generating ozone in a state where indoor air is not guided.

An indoor blower 20 is disposed between the front and rear heat exchanger portions 8A and 8B of the heat exchanger 8 formed in an umbrella shape in a side view. The indoor blower 20 includes a fan motor disposed in a space on one side end of the indoor unit main body 1 and a cross-flow fan (cross flow fan) 21 in which one support shaft is coupled to the rotation shaft of the fan motor. The
By driving the indoor blower 20, indoor air is sucked into the indoor unit body 1 from the front and upper suction ports 4 and 5, and the air cleaning unit 17 and the heat exchanger 8 are moved from the front and upper air filters 11A and 11B. An air passage 24 that circulates and is blown out from the air outlet 6 via the indoor blower 20 is formed.

The lower end portion of the front heat exchanger portion 8A is placed on the front drain pan 22a, and the lower end portion of the rear heat exchanger portion 8B is placed on the rear drain pan 22b. The front and rear drain pans 22a and 22b receive drain water dripped from the respective heat exchanger portions 8A and 8B, and can drain to the outside via a drain hose (not shown).
The outer surfaces of the side walls of the front and rear drain pans 22 a and 22 b are provided close to the indoor fan 20, and constitute a nose for the cross flow fan 21. A casing 23 is provided between the side walls of the front and rear drain pans 22a and 22b serving as noses and each side portion of the air outlet 6, and the space surrounded by the casing 23 communicates the nose and the air outlet 6. A part of the air passage 24 is formed.

FIG. 3 is a schematic configuration diagram of the cross-flow fan 21.
The cross-flow fan 21 includes a disk-shaped end plate 25 provided on both sides in the axial direction, and a plurality of disk-shaped intermediate partition plates juxtaposed at a predetermined interval between the both side end plates 25. 26, and a plurality of blades 27 that pass through the groove portions provided along the peripheral end portions of the both side end plates 25 and the intermediate partition plate 26, and are attached and fixed by means such as adhesion.
A hole 25a is provided in the shaft core portion of the right end plate 25 in the drawing, and the rotation shaft of the fan motor is inserted and fixed therein. A support shaft 25b protrudes outwardly from the shaft core portion of the left end plate 25 in the drawing, and this support shaft 25b is supported by a bearing portion provided on the side of the cross flow fan 21.

The right end plate 25 in the figure has a plurality of arc-shaped elongated holes b between the hole 25a and the peripheral end, and the left end plate 25 has a space between the support shaft 25b and the peripheral end. Are provided with a plurality of holes c. The intermediate partition plate 26 is provided with a circular opening d at the shaft core portion excluding the attachment portion of the blade 27.
The cross-flow fan 21 can be driven to rotate to suck air from the circumferential direction and blow it out in the circumferential direction. On the other hand, the circular arc-shaped hole b provided in one end plate 25 and the opening portion d provided in the intermediate partition plate 26 and the hole portion c provided in the other end plate 25 are in communication with each other. . That is, the dust collection opening 28 including the hole b and the like is opened inside the blade 27 constituting the cross flow fan 21.

As shown in FIG. 1 again, in a state where both the fan cleaning device B and the airflow changing device C are gathered in one place in the casing 23 that forms a part of the air passage 24 from the crossflow fan 21 to the blowout port 6. Mounted. FIG. 1 shows a state where the airflow changing device C is operating.
A part of the outer peripheral side of the casing 23 is provided with a storage recess 30 having a predetermined length in the circumferential direction and facing the entire length of the cross flow fan 21 in the axial direction. Both the fan cleaning device B and the airflow changing device C are provided with a flat plate member having a predetermined thickness and a width dimension and a length dimension that are accommodated in the recess 30 for accommodation. That is, the fan cleaning device B includes a plate-like cleaning member 40, and the airflow changing device C includes an airflow changing plate 50.

One end of the plate-like cleaning member 40 is provided with a rotation fulcrum 41 on the uppermost stream side of the air passage 24, and the other end is rotatably supported as a free end. A cleaning portion 42 is provided at an end portion which is a free end, and a brush is attached here. The brush 42 has a thickness substantially the same as the thickness of the plate-like cleaning member 40 and is provided over the entire length in the width direction.
One end of the airflow changing plate 50 is rotatably supported by the casing 23 via a rotation fulcrum 51, and the other end is a free end. The rotation fulcrum 51 is provided on the most downstream side of the air passage 24, and the free end is located on the upstream side of the air passage 24. The airflow changing plate 50 is a complete flat plate, and no member is attached to the free end. The airflow changing plate 50 and the plate-like cleaning member 40 are connected to one common driving unit (shown in FIG. 4) and are driven simultaneously.

FIG. 4 is an external perspective view of the drive unit 60 that drives the plate-like cleaning member 40 and the airflow changing plate 50.
The pivotal fulcrum 41 of the plate-like cleaning member 40 and the pivotal fulcrum 51 of the airflow changing plate 50 protrude from the casing 23 forming a part of the air passage 24 and are fitted to the gears in the gear cover 61. An idle gear, a cam, a link mechanism and the like (not shown) are interposed between these gears, and are connected to a rotation shaft of a drive motor 62 attached to the outer surface of the gear cover 61.
Therefore, when the drive motor 62 is driven, the plate-like cleaning member 40 and the airflow changing plate 50 are configured to be rotationally displaced simultaneously. This basically coincides with the configuration in which the two outlet louvers 7a and 7b provided at the outlet 6 are displaced at the same time and with different rotational postures.

FIG. 5 is a cross-sectional view of the main part showing a state in which the plate-like cleaning member 40 and the airflow changing plate 50 are both housed in the housing recess 30.
When the plate-like cleaning member 40 and the airflow changing plate 50 are not operating, both are stored in the storage recess 30. At this time, the plate-shaped cleaning member 40 is stored on the lower side, and the airflow change plate 50 is stored on the upper side of the plate-shaped cleaning member 40. In other words, the plate-like cleaning member 40 is placed directly on the bottom surface of the storage recess 30, the airflow changing plate 50 covers the plate-like cleaning member 40 entirely, and the upper surface of the airflow changing plate 50 is the surface of the casing 23. It becomes the wall surface of substantially the same height.
FIG. 6 shows a state during operation of the airflow changing plate 50 described later, and is also a partially enlarged view of FIG. 1 described above.

That is, the airflow changing plate 50 rises from the state of FIG. 5 with the rotation fulcrum 51 as a fulcrum, and the plate-like cleaning member 40 rotates with the rotation fulcrum 41 as a fulcrum at the timing when it is almost upright. At this time, since the airflow changing plate 50 is almost upright, the rotation of the plate-like cleaning member 40 that has been on the lower side is smoothly performed without any trouble.
FIG. 7 shows a state in which the plate-like cleaning member 40 performs a cleaning action on the cross flow fan 21. The plate-like cleaning member 40 rotates in the same direction from the state of FIG. 6 and stands up in an almost upright state shown in FIG. At the next timing, the airflow changing plate 50 rotates and stops at a position where the tip abuts against the side of the plate-like cleaning member 40. Since the crossflow fan 21 rotates in the clockwise direction, the airflow changing plate 50 comes into contact with the plate-like cleaning member 40 from the counter-rotating direction of the crossflow fan 21.

As shown in FIG. 2 again, an electrical component box 70 is juxtaposed on one side of the heat exchanger 8 (right side in the figure). In the electric component box 70, the indoor blower 20, the drive unit of the air filter cleaning device A, the fan cleaning device B, and the airflow changing device C are based on signals sent from the remote controller and signals sent from various sensors. The drive part 60, the drive part of the exhaust apparatus D mentioned later, the semiconductor part which controls another electric component, and the control part S which is an aggregate | assembly of an electrical component are accommodated.
The exhaust device D is provided on the side of the heat exchanger 8 opposite to the electrical component box 70 (left side in the figure). The exhaust device D is provided adjacent to a side portion of the cross flow fan 21 constituting the indoor blower 20 and has an axis on an extension of the axis of the cross flow fan 21.

Next, the exhaust device D will be described in detail.
FIG. 8 is an explanatory view of the operation of the air filter cleaning device A and the fan cleaning device B with respect to the exhaust device D, and FIG. 9 is a perspective view of a part of the exhaust device D and the air filter cleaning device A.
The exhaust device D includes dust removed by the air filter cleaning device A and the fan cleaning device B, air on the secondary side of the heat exchanger 8 in which the cross-flow fan 21 is disposed, and an electrostatic precipitator 18 generates ozone. When functioning as a device, it has a function of discharging the dirty air containing ozone after sterilizing the interior of the indoor unit body 1 to the outdoors.
More specifically, as shown in FIG. 8, an air filter guide path 32 for guiding the removed dust is interposed between the air filter cleaning device A and the exhaust device D. A fan guide path 33 is formed between the fan cleaning device B and the exhaust device D to guide the removed dust and the air on the secondary side of the heat exchanger after passing through the heat exchanger 8.

The air filter guide path 32 and the fan guide path 33 include damper mechanisms 34 and 35 that open and close in reverse directions. The damper mechanism 34 provided in the air filter guide path 32 is a wind damper, and the damper mechanism 35 provided in the fan guide path 33 is a ventilation damper connected to the drive unit.
The air filter guide path 32 is connected to a part of the peripheral surface of the fan casing 36 constituting the exhaust device D. The fan guide path 33 is opposed to an introduction port 37 formed in the exhaust device D. The introduction port 37 is located at a position facing the bearing portion of the cross-flow fan 21 and is provided by the ventilation damper 35. Opened and closed.

The air filter guide path 32 and the fan guide path 33 are combined in the exhaust device D. Therefore, the air filter cleaning device A, the fan cleaning device B, and the ozone generator that is the electrostatic precipitator 18 can be handled by one exhaust device D, and the indoor unit body 1 is made compact and simplified by common parts. Can be obtained.
The exhaust device D includes a ventilation fan 38 formed of a multiblade fan connected to a motor in a fan casing 36. The axial centers of the ventilation fan 38 and the cross flow fan 21 are on the same axis L, the introduction port 37 is formed between them, and the ventilation damper 35 is interposed.

Since the cross-flow fan 21 is disposed on the secondary side, which is a portion after the room air has passed through the heat exchanger 8, the inlet 37 also opens on the secondary side of the heat exchanger 8. Further, the fan casing 36 of the exhaust device D is connected to an auxiliary guide path H that has an open end on the primary side, which is a part before flowing through the heat exchanger 8, and guides the primary air.
The ventilation damper 35 closes the inlet 37 to substantially seal the exhaust device D, or opens the inlet 37 to open the exhaust device D to the secondary side of the fan cleaning device B and the heat exchanger 8. The switching is controlled by selecting either the auxiliary guide path H opened to the primary side of the heat exchanger 8 or opening the auxiliary guide path H.

An exhaust duct 39 is connected to the fan casing 36, and the exhaust duct 39 extends through the wall K of the house and has an open end extending outside.
As shown in FIG. 9, a discharge box 12 a is provided at one side of the air filter cleaning device A, and the discharge box 12 a and the exhaust device D are connected by a connection hose 71. The connection hose 71 is bent so as to form a gentle curve as a whole, and consideration is given so that dust that conducts inside does not get clogged.
The exhaust device D is provided with a damper case 72 having a mouth to which the connection hose 71 is connected, and the wind damper 34 is provided in the damper case 72. That is, the air hose 71 and the damper case 72 constitute the air filter guide path 32.

When a wind pressure (negative pressure) higher than a predetermined pressure is applied to the connection hose 71, the free end of the wind damper 34 is pushed upward by the wind pressure, and the air filter guide path 32 is opened. If the wind pressure of a predetermined pressure or more disappears from this state, or if positive pressure is applied, the wind damper 34 blocks the air filter guide path 32.
When the air conditioner indoor unit is configured as described above and the operation switch of the remote control is turned on, the movable panel 2A opens the front suction port 4 in accordance with the designation of the cooling operation and the heating operation. The wind direction postures of the blowout louvers 7a and 7b provided in the blowout port 6 are set. At the same time, the indoor blower 20 performs a blowing action, while the compressor of the outdoor unit is driven to start the refrigeration cycle operation.

Indoor air is sucked into the indoor unit body 1 from the front suction port 4 and the upper suction port 5. Then, the dust contained in the room air is captured through the front air filter 11A and the upper air filter 11B. Furthermore, finer dust is captured through the air cleaning unit 17 and is guided to the heat exchanger 8 to perform a heat exchange action.
The air after the heat exchange is guided along the casing 23 forming the blow-out air passage 24 through the cross-flow fan 21 which is the secondary side, and is guided from the blow-out port 6 to the blow-out louvers 7a and 7b. Continued efficient air-conditioning operation. At this time, the plate-like cleaning member 40 constituting the fan cleaning device B and the airflow changing plate 50 constituting the airflow changing device C are housed in the housing recess 30.

In particular, the airflow changing plate 50 that is on the upper side of the plate-like cleaning member 40 and covers the entire surface thereof forms the same surface as the wall surface of the casing 23, and does not protrude into the air passage 24. In other words, it is not necessary to have the blowing resistance of the heat exchange air that is guided to the blowing path 24 and blown out from the outlet 6.
If the air conditioning operation is continued for a long period of time, dust trapped from room air inevitably accumulates on the front air filter 11A and the upper air filter 11B, and is also captured by the front, upper air filters 11A and 11B and the air cleaning unit 17. The dust that has not been passed passes through the heat exchanger 8 and adheres to the crossflow fan 21 constituting the indoor blower 20.

The control unit S sends an operation start signal to the air filter cleaning device A and the fan cleaning device B in order to perform an in-machine clean operation after a predetermined cumulative air conditioning operation time has elapsed. Or you may set so that an operation start signal can be sent to each cleaning apparatus A and B from the control part S by a user pressing the cleaning switch of a remote control arbitrarily.
The control unit S sends a signal to the drive unit of the movable panel 2A to close the front suction port 4, and sends a signal to the drive unit of the blowout louvers 7a and 7b to close the blowout port 6. By making the indoor unit main body 1 into a substantially sealed structure in advance, it is possible to prevent the collected dust from leaking as much as possible.

An operation start signal is first sent to the air filter cleaning device A at the timing after completion of these closures. In the air filter cleaning device A, the front air filter 11A is moved to the upper air filter 11B side, and the roll brush 13 in the dust box 12 is rotationally driven to scrape off dust adhering to the front air filter 11A. The dust scraped off is received in the dust receiving passage 14 in the dust box 12.
When the front air filter 11A moves to the upper surface side of the upper air filter 11B, it is moved in the direction toward the original front suction port 4 and the roll brush 13 removes dust remaining on the front air filter 11A. After the front air filter 11A returns to the original position, the upper air filter 11B is moved to the front air filter 11A side, and the attached dust is removed.

The dust scraped off is received in the dust receiving passage 14 in the dust box 12. When the upper air filter 11B moves to the front side of the front air filter 11A, the upper air filter 11B is moved in the direction toward the original upper suction port 5, and the roll brush 13 removes dust remaining on the upper air filter 11B.
Thereafter, the operation as the air filter cleaning device A is stopped. Both the front air filter 11A and the upper air filter 11B are dust-removed twice, and the cleaning effect becomes perfect. Since the removed dust is collected in the dust receiving passage 14 of the dust box 12, the control unit S sends an operation signal to the exhaust device D and discharges the collected dust to the outdoors.

In the exhaust device D, the ventilation damper 35 rotates to close the introduction port 37, close the fan guide path 33, and close the auxiliary guide path H. Next, the ventilation fan 38 is driven to rotate, and the inside of the fan casing 36 is in a negative pressure state. As a result, the inside of the damper case 72 is also in a negative pressure state, and the wind damper 34 opens the air filter guide path 32.
A negative pressure is applied from the air filter guide path 32 to the dust receiving passage 14 in the dust box 12, and the collected dust is guided from the air filter guide path 32 into the fan casing 36 and discharged to the outside from the exhaust duct 39. The

After discharging the dust collected by the air filter cleaning device A to the outdoors, the control unit S sends a work start signal to the fan cleaning device B and sends a switching signal to the ventilation damper 35. The ventilation damper 35 opens the inlet 37, and the auxiliary guide path H is closed. In the fan cleaning device B, the airflow change plate 50 stored in the storage recess 30 is erected, and the plate-shaped cleaning member 40 is urged to rotate when the airflow change plate 50 reaches a predetermined angle.
After the state shown in FIG. 5 is changed to the state shown in FIG. 6, the plate-like cleaning member 40 is further erected, and the airflow changing plate 50 is rotated in the storing direction in the storing recess 30. Eventually, as shown in FIG. 7, the plate-like cleaning member 40 is erected to bring the tip brush 42 into contact with the blade 27 of the cross flow fan 21. The airflow changing plate 50 is inclined so that the tip contacts the side of the plate-like cleaning member 40.

In addition, the control unit S controls the cross flow fan 21 to rotate reversely from the air-conditioning operation, or to repeat the forward rotation drive and the reverse rotation drive. As the cross flow fan 21 rotates, the bristles of the brush 42 come into sliding contact with each other, and the dust attached to the blades 27 of the cross flow fan 21 is removed.
The cross flow fan 21 is driven to rotate in the clockwise direction, and the brush 42 removes dust adhering to the blade 27. On the other hand, the plate-like cleaning member 40 tends to fall by receiving a biasing force in the rotational direction of the cross-flow fan 21, but the airflow changing plate 50 supports from the counter-rotation direction side, so that it does not fall down and hinders dust removal. Can continue without.

At the same time, the introduction port 37 and the dust collection opening 28 of the cross flow fan 21 face each other via a fan guide path 33 that is a gap between the end plate 25 of the cross flow fan 21. Due to the low-speed rotation of the cross-flow fan 21, room air is sucked into the indoor unit body 1 from the upper suction port 5 that is always open, and flows through the heat exchanger 8. The secondary air flowing out of the heat exchanger 8 is sucked into the fan casing 36 from the inlet 37 by the operation of the ventilation fan 38.
Further, negative pressure is applied to the dust collection opening 28 of the crossflow fan 21 through the fan guide path 33. The dust scraped off from the cross flow fan 21 is guided to the fan guide path 33 from the dust collection opening 28, merges with the secondary side air at the introduction port 37, and is introduced into the exhaust device D. And dust is discharged | emitted outside via the exhaust duct 39 with secondary side air.

At this time, the blowout port 6 is closed by the blowout louvers 7 a and 7 b, the cross flow fan 21 is rotated at a low speed, and the airflow changing plate 50 and the plate-like cleaning member 40 are protruded into the blower passage 24. For this reason, the airflow changing plate 50 and the plate-like cleaning member 40 act as a pseudo nose, and the airflow forms a circulating flow that circulates through the crossflow fan 21 and the secondary side of the heat exchanger 8 that is around it.
The circulating flow is finally sucked from the inlet 37 of the exhaust device D as the secondary air of the heat exchanger 8 and exhausted to the outdoors. Therefore, the airflow including dust scraped off from the crossflow fan 21 is scattered around the crossflow fan 21 or attached to each component, and the cleanliness inside the indoor unit body 1 is maintained.

When the fan cleaning device B is in operation, air pressure is applied from the fan casing 36 to the damper case 72, and the wind damper 34 prevents the flow of airflow toward the connection hose 71, so that the airflow from the connection hose 71 to the dust box 12 is reduced. There is no backflow. As described above, when the ventilation damper 35 opens the fan guide path 33, the wind damper 34 closes the air filter guide path 32.
As the in-machine clean operation, in order to kill mold spores adhering to the surface of the cross-flow fan 21, a sterilization operation can be performed in which the ozone generator, which is the electric dust collector 18, is activated to fill the interior of the indoor unit body 1 with ozone. . It is necessary to discharge the ozone used for the sterilization operation to the outside as it is. Moreover, the exhaust operation which discharges the dirty air and moisture which fill the indoor unit main body 1 outdoors can also be selected.

When these operations are selected, the ventilation damper 35 opens the inlet 37 and holds the airflow changing plate 50 in an upright position as shown in FIGS. It is also possible to close the front suction port 4 with the movable panel 2A, close the blowout port 6 with the blowout louvers 7a, 7b, and rotate the cross-flow fan 21 at a low speed. It is the same as when driving.
In the sterilization operation, ozone is generated by the electric dust collector 18, and in the exhaust operation, ozone is not generated. Since the airflow changing plate 50 protrudes into the air passage 24, the airflow changing plate 50 acts as a pseudo nose, and the airflow circulates through the cross flow fan 21 and the secondary side of the heat exchanger 8 that is around it. R (only shown in FIG. 1) is formed.

Circulating flow R composed of dirty air and moisture that is either ozone sterilized or not ozone sterilized is finally sucked from the inlet 37 of the exhaust device D as the secondary air of the heat exchanger 8 and exhausted to the outside. At this time, since the introduction port 37 is opened, the wind damper 34 closes the air filter guide path 32 and the dirty air is not guided to the air filter cleaning device A.
In particular, in the sterilization operation and the exhaust operation, the airflow changing plate 50 is protruded into the air passage 24 so that the airflow generated by the rotation of the cross flow fan 21 is forcibly circulated in the indoor unit body 1. The dirty air during cleaning does not leak from the air outlet 6 to the indoor side, and the dirty air in the indoor unit body 1 can be discharged to the outside in a short time. In-machine clean operation can be performed efficiently, the interior of the indoor unit body 1 is kept clean for a long period of time, and air-conditioning capability during installation is maintained.

An indoor ventilation mode can also be selected. At this time, the ventilation damper 35 opens the auxiliary guide path H and closes the introduction port 37. The movable panel 2A opens the front suction port 4, but the blowout louvers 7a and 7b close the blowout port 6. In addition, since the ventilation fan 38 is rotationally driven, indoor air before being led into the indoor unit main body 1 and led to the heat exchanger 8 (primary side) is directly discharged to the outdoors via the exhaust device D.
Since the auxiliary guide path H is open, the wind damper 34 closes the air filter guide path 32 and the primary air is not guided to the air filter cleaning device A. Thus, the air conditioner can perform not only air conditioning operation and clean operation in the indoor unit body 1 but also indoor ventilation operation, which is extremely effective.
Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. Various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the above-described embodiments.

The schematic sectional drawing of the air conditioner indoor unit based on one embodiment in this invention. The front view of the indoor unit which removed the front panel based on the embodiment. The schematic block diagram of the crossflow fan based on the embodiment. The external appearance perspective view of the drive part in the fan cleaning apparatus based on the embodiment. Sectional drawing of the principal part which shows the state by which the plate-shaped cleaning member and the airflow change board are accommodated in the recessed part for accommodation based on the embodiment. Sectional drawing of the principal part explaining the action | operation attitude | position of the airflow change board at the time of the sterilization operation | movement or exhaust operation based on the embodiment. Sectional drawing of the principal part explaining the action | operation attitude | position of the plate-shaped cleaning member based on the embodiment. The figure explaining the flow of dust at the time of the effect | action of the air filter cleaning apparatus and fan cleaning apparatus which concern on the embodiment. The external appearance perspective view of a part of air filter cleaning apparatus and exhaust apparatus based on the embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Indoor unit main body, 4, 5 ... (front part, upper part) Suction inlet, 6 ... Air outlet, 24 ... Air flow path, 11 ... Air filter, 8 ... Heat exchanger, 20 ... Air blower, 21 ... Cross-flow fan, 23 ... Case, R ... Circulating flow, C ... Airflow changing device, 51 ... Rotation fulcrum, 50 ... Airflow changing plate, 60 ... Drive part, 2A ... Moving panel, 7a, 7b ... Blowing louver, S ... Control part, 18 ... Ozone generator (electric dust collector), D ... exhaust device.

Claims (1)

An air filter, a heat exchanger, and a cross-flow fan that constitutes a blower on the ventilation secondary side of the heat exchanger are sequentially arranged in the air passage that communicates the air suction port and the air outlet of the indoor unit body. In an indoor unit of an air conditioner equipped with an ozone generator that is controlled during sterilization operation in the machine body and an exhaust device that takes in the secondary side air of the heat exchanger and discharges it to the outside ,
A casing that forms the air blowing path from the periphery of the cross-flow fan to the air outlet,
An airflow change plate that is opposed to the casing over the entire axial length of the crossflow fan and that is formed in a flat plate shape and whose one end is supported by the casing via a rotation fulcrum, and the airflow change plate is rotated. It is equipped with an airflow changing device that consists of a driving unit that urges
The airflow changing plate constituting the airflow changing device is
The pivot point is provided on the downstream side of the air passage, and the free end is directed on the upstream side of the air passage;
When not in operation, it is housed in the casing forming the air passage and is part of the wall surface,
During the flight of the sterilization operation, is protruded into air passage by the driving unit, the distal end portion is close to the outer periphery of the cross flow fan to an action of the pseudo nose, the horizontal flow in the indoor unit body with the operation of the blower The airflow generated by the rotation of the fan is guided to the exhaust device by forming a circulating flow that forcibly circulates the crossflow fan and the secondary side of the heat exchanger around it.
An indoor unit of an air conditioner, characterized in that.

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