JP4083495B2 - Air conditioner indoor unit - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an air conditioner composed of an indoor unit and an outdoor unit, and more particularly to adding an indoor ventilation function in an indoor unit.
[0002]
[Prior art]
An air conditioner composed of an indoor unit and an outdoor unit is often used. In an indoor unit, the main body includes a suction port and a blow-out port, and a heat exchanger, a blower, and the like are accommodated inside the main body. An air filter is attached to the front surface of the heat exchanger so as to capture dust before being led to the heat exchanger.
By the way, not only does the user always perform indoor air conditioning, but depending on the situation, there are cases where it is desired to ventilate the room effectively and quickly without opening the window.
[0003]
For example, when multiple people smoke at the same time in the living room, the smoke fills up and there is an unpleasant odor that makes them uncomfortable. The following conditions can be considered.
Normally, a ventilation fan is provided in a kitchen or the like, but there are not many ventilation fans dedicated to the living room. Therefore, in the above case, it is necessary to cope by opening the window even a little, or by putting up with it without opening the window, and anyway, comfort is impaired.
[0004]
Therefore, products have been provided that extend the indoor unit body sideways and have a ventilation fan at a position adjacent to the heat exchanger. Ventilation openings are opened in the front and rear ventilation fan facing parts and the mounting wall part of the indoor unit main body, and the indoor air is discharged to the outside by the operation of the ventilation fan.
[0005]
[Problems to be solved by the invention]
By the way, in the state immediately after the cooling operation or the dehumidifying operation is stopped, moisture (drain water) is attached to other components such as the heat exchanger, and the interior of the indoor unit main body has a high humidity atmosphere. It has become. If left as it is, the adhering moisture remains without evaporating, causing corrosion or mold.
A normal air conditioner does not have a function of evaporating moisture remaining in the indoor unit body. Depending on the model, after the cooling operation or dehumidifying operation is completed, the air blowing operation without heat exchange operation is continued for several minutes to dry the inside of the main body, and it is insufficient and moisture is blown into the room There is.
[0006]
Moreover, in the indoor unit provided with the ventilation fan described above, since the heat exchanger and the ventilation fan are arranged in parallel, even if the ventilation fan is continuously operated after the above operation is completed, the wind is blown through the ventilation opening. Efficient drying of the heat exchanger and the interior of the indoor unit main body cannot be achieved only by distribution.
The present invention has been made in view of the above circumstances, and its purpose is not only to have an original air conditioning function, but also to adhere to the inside of the main body including a heat exchanger after the completion of the cooling operation or the dehumidifying operation. Therefore, it is intended to provide an indoor unit of an air conditioner that enables the outdoor discharge of moisture to be performed, and the inside of the main body is completely dried to suppress generation of mold and the like, thereby increasing cleanliness.
[0007]
[Means for Solving the Problems]
In order to satisfy the above object, the indoor unit of the air conditioner of the present invention is provided with a suction port at the front and upper part, and an indoor unit body provided with a blowout port at the front lower part, facing the front suction port and the upper suction port. And a heat exchanger formed in a substantially inverted V shape when viewed from the side, and air that is located inside the heat exchanger and sucks room air from the front and upper suction ports and passes through the heat exchanger and blows out. An indoor blower that blows out from the mouth , an air filter that is attached between the heat exchanger and the front suction port and the upper suction port to capture and remove dust in the room air;
A unit base that is installed inside one side part of the heat exchanger side surface, forms one side part and matches the umbrella-shaped combination shape of the heat exchanger, a blower mechanism that forms the other side part, and these unit bases And a blower mechanism, and a damper provided with a gear portion along the outer peripheral edge, a drive motor, a drive gear coupled to the rotating shaft of the drive motor, and at least two small gears. A ventilation unit comprising a damper drive mechanism meshing with a gear portion of the damper;
The ventilation unit distributes the primary side air ventilation mode that sucks the primary side air that has been passed through the air filter and trapped dust before being led to the heat exchanger and then discharges it to the outside, and the heat exchanger. The secondary side air ventilation mode that sucks in the secondary side air after it has been discharged and discharges it outdoors, and the ventilation damper that blocks the discharge path to the outside according to environmental conditions, etc., and blocks the flow between the interior of the indoor unit body and the outdoors Switching to fully closed mode is possible .
[0009]
By adopting means to solve such problems, in addition to having the original air conditioning function, it is possible to discharge the moisture adhering to the heat exchanger etc. after the cooling operation or the dehumidifying operation, The body is completely dried and the occurrence of mold and the like is suppressed to improve the cleanliness of the body.
[0010]
Further, the ventilation unit discharges the primary air to the outside, thereby suppressing heat loss of the heat exchanger and performing an efficient indoor ventilation operation.
Furthermore, according to environmental conditions etc., distribution | circulation between the inside of an indoor unit main body and the outdoors is interrupted | blocked, the penetration | invasion of dust, noise, etc. from the outdoors is prevented, and it can switch to the same structure as a normal air conditioner suitably.
In addition, the damper that changes the flow path in the ventilation unit is equipped with a damper drive mechanism in which the drive gear and at least two small gears are engaged with each other, so that the sliding resistance of the damper drive is small and smooth rotation motion can be guaranteed. .
[0011]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a perspective view of the appearance of an indoor unit constituting the air conditioner, FIG. 2 is a schematic longitudinal sectional view of the indoor unit, and FIG. 3 is a perspective view showing the interior of the indoor unit with the front panel removed. is there.
[0012]
The indoor unit main body 1 is composed of a front panel 2 and a rear plate 3, and has a horizontally long shape with an extremely long width direction with respect to the vertical direction. The front panel 2 is curved and protrudes toward the front side, and includes side plates 1a on both the left and right sides. The rear plate 3 has a horizontally long rectangular shape and is attached to the wall surface of the air-conditioned room.
A front suction port 4 is opened at a part of the front side of the front panel 2, and a movable panel 2 a supported by an opening / closing drive mechanism 5 is fitted therein. When the operation is stopped, the movable panel 2a is flush with the front panel 2 and closes the front suction port 4. However, during operation, the movable panel 2a is controlled so as to project and displace to the front and open the front suction port 4.
[0013]
An upper suction port 6 is provided over the front panel 2 and the rear plate 3. A frame-like crosspiece 7 is fitted into the upper suction port 6 and is partitioned into a plurality of spaces by this crosspiece.
A decorative plate 2b made of a translucent material constituting a part of the front panel 2 is provided in the lower part of the movable panel 2a over the width direction of the indoor unit body 1. Two blowing louvers 8a and 8b are provided in parallel on the lower side of the decorative plate 2b.
[0014]
The blowout louvers 8a and 8b can open and close the blowout opening 9 provided along the lower front surface of the indoor unit body 1, and can change the posture angle according to the operating conditions and set the blowout direction of the heat exchange air. ing.
In the indoor unit main body 1, a heat exchanger 10 formed in a substantially inverted V shape by a front heat exchanger portion 10A and a rear heat exchanger portion 10B is disposed. The front heat exchanger portion 10A is formed in a substantially parallel curved shape with a gap with the front panel 2, and the rear heat exchanger portion 10B is formed in a straight shape and inclined obliquely with the upper suction port 6 Then face each other.
[0015]
On the other hand, an air filter 11 is attached in the indoor unit body 1 facing the front suction port 4 and the upper suction port 6. The air filter 11 is interposed between each of the suction ports 4 and 6, the front heat exchanger section 10 </ b> A and the upper heat exchanger section 10 </ b> B, and is detachable from between the open upper end of the blowout opening 9 and the lower end of the front panel 2. Inserted.
The electric dust collector 12 is attached to the front side of the front heat exchanger section 10A of the heat exchanger 10 and at a position shifted to the right end side when viewed from the front with respect to the indoor unit body 1. The electrostatic precipitator 12 includes a charge side electrode that applies a charge to dust in the flowing air, and a dust collection side electrode that attracts and captures the charged dust.
[0016]
The electrostatic precipitator 12 is an ozone generator that generates a large amount of ozone when a high voltage is applied to the charge side electrode so that the potential difference from the dust collection side electrode is larger than that during normal dust collection. At this time, the amount of ozone generated becomes larger by stopping or operating the blower 13 at a very low speed in order to limit the flow of ambient air.
An indoor blower 13 is disposed between the front and rear heat exchanger portions 10 </ b> A and 10 </ b> B of the heat exchanger 10 and between the outlet 9. That is, the indoor blower 13 is located inside the heat exchanger 10 formed in an umbrella shape.
[0017]
As schematically shown in FIG. 4A, the indoor blower 13 includes a fan motor 13M and a cross-flow fan 13F in which one support shaft a is mechanically connected to the rotation shaft of the fan motor. The
The axial direction length La of the cross flow fan 13F is substantially the same as the width direction dimension L of the heat exchanger 10, and the position is shifted to the right side of the heat exchanger 10 as a whole when viewed from the front.
[0018]
That is, the left end c of the cross flow fan 13F is on the inner side of the left side d of the heat exchanger 10, and the right end e of the cross flow fan 13F protrudes outward from the right side f of the heat exchanger 10. ing.
Further, as shown in FIG. 4B, a cross flow fan 13F having an axial length Lb shorter than the width dimension L of the heat exchanger 10 is provided, and a left end c of this fan is the same as that in FIG. Although located, the right end g may be aligned with the right side f of the heat exchanger 10.
[0019]
In any case, the other (left side) support shaft h of the cross-flow fan 13F constituting the indoor blower 13 is supported by a ventilation unit 15 described later. The ventilation unit 15 is arranged in a space space beside the indoor fan 13 formed by shifting the position of the indoor fan 13 with respect to the heat exchanger 10.
The left side surface j of the ventilation unit 15 is aligned with the left side surface d of the heat exchanger 10 at substantially the same position, and the ventilation unit 15 together with the indoor blower 13 is attached to the inside of the heat exchanger 10 formed in an umbrella shape. .
[0020]
As shown in FIG. 2 again, the lower end portion of the front heat exchanger portion 10A is placed on the front drain pan 16a, and the lower end portion of the rear heat exchanger portion 10B is placed on the rear drain pan 16b. The drain water dripped from the parts 10A and 10B is received, and can be drained to the outside through a drain hose (not shown).
Moreover, the outer surface of a part of the side walls of the front and rear drain pans 16a and 16b is provided at a position close to the indoor fan 13, and these constitute a nose for the cross-flow fan 13F of the indoor fan 13.
[0021]
A partition wall member 17 connects the side wall portions of the front and rear drain pans 16 a and 16 b constituting the nose and each side portion of the outlet 9. A space surrounded by the partition member 17 is a blowout air passage 18 that communicates the nose and the blowout opening 9.
Next, the ventilation unit 15 will be described in detail.
5 is a cross-sectional view of the ventilation unit 15, and is a view for explaining the arrangement of the other components. FIG. 6 is an exploded perspective view of the ventilation unit, and FIG. 7 is a side view of one side of the ventilation unit. FIG. 8 is a perspective view of the other side of the ventilation unit.
[0022]
The ventilation unit 15 includes a unit base 20 that forms one side surface portion thereof, a blower mechanism 30 that forms the other side surface portion, a damper 40 and a damper drive interposed between the unit base 20 and the blower mechanism 30. And a mechanism 45.
The unit base 20 includes a vertical portion 20a, and an inclined portion 20b is formed along an edge other than the lower end edge of the vertical portion, and the unit base 20 is horizontally bent integrally from the edge of the inclined portion in the horizontal direction. A portion 20c is provided.
[0023]
The upper part of the vertical part 20a is formed so as to protrude in a substantially triangular shape in a side view, and an umbrella-like combined shape of the front heat exchanger part 10A and the rear heat exchanger part 10B constituting the heat exchanger 10 and It matches.
A rising piece k is formed along the edge of the horizontal portion 20c, the end plate t of the heat exchanger 10 is aligned there, and the fin F constituting the heat exchanger 10 is placed on the horizontal portion 20c. . When the heat exchanger 10 is placed on the horizontal portion 20c, a gap is formed at a portion facing the inclined portion 20b.
[0024]
A circular mounting opening 21 is opened at a substantially central portion of the vertical portion 20a, and a rib 22 is formed along the peripheral surface of the opening and bent toward the inner surface of the vertical portion 20a. In addition, reinforcing ribs 23 are provided radially on the outer surface side of the vertical portion 20 a along the periphery of the mounting opening 21.
On the inner surface side of the vertical portion 20a, a plurality (seven) of full-closing piece portions 24 are provided along a substantially half circumference of the opening portion 21 with a predetermined interval. Between the full-closing pieces 24, half of the full-closing pieces are opened, and this opening is called a secondary ventilation port 25. That is, three secondary ventilation ports 25 are provided.
[0025]
A bearing member 26 is fitted and fixed to the mounting opening 22 of the vertical portion 20a, and a bearing portion 27 is constituted by these. As described above, the bearing portion 27 pivotally supports the other (left side) support shaft h of the cross flow fan 13 </ b> F constituting the indoor blower 13.
On the inner surface side of the vertical portion 20a, two stays 28a project from the same radius of curvature. These stays 28a are formed so that only their projecting end portions have a small diameter, and small gears 46 constituting the damper drive mechanism 45 are rotatably fitted in each of the stays 28a, and are prevented from coming off by appropriate means.
[0026]
In the vicinity of the stay 28a, a plurality of stays 28b having a height higher than the stay 28a are provided. A screw hole is provided in the axial direction from the projecting end face of each stay 28b, and a mounting screw m for mounting and fixing the air blowing mechanism 30 is screwed.
Only the stay 28b provided in the vicinity of the full closing piece 24 is integrally provided with a receiving portion 29 adjacent to the peripheral portion. A driving motor 47 constituting a damper driving mechanism 45 is attached and fixed to the receiving portion 29, and a driving gear 48 connected to the rotating shaft of the driving motor is rotatably supported.
[0027]
On the other hand, a fitting portion 41, which is a hole provided in the center portion of the damper 40, is rotatably fitted on the outer peripheral surface of the rib 21 constituting the bearing portion 27. The damper 40 is formed in a substantially dish-shaped cross section in the radial direction from the fitting portion 41, and a gear portion 42 is provided along a circular outer peripheral edge.
The gear portion 42 of the damper 40 is assembled so that the two small gears 46 and the driving gear 48 described above are engaged with each other. Accordingly, the drive motor 47 rotates the drive gear 48 to rotate the damper 40, and the small gear 46 functions as an idle gear with respect to the damper gear portion 42.
[0028]
Furthermore, between the fitting part 41 and the outer peripheral gear part 42 in the damper 40, a plurality of (three ports) guiding ventilation ports 43 are provided in a part in the circumferential direction. These guide vents 43 have exactly the same opening size and shape as the secondary vent 25 provided in the unit base vertical portion 20a.
The crosspieces n formed between the guide ventilation ports 43 have the same distance as the mutual distance between the full-closing pieces 24. While the damper 40 is fitted into the rib 21 and has a gap with the inner surface of the vertical portion 20a, one side surface of the damper 40 is always slid onto the edge of the full-closing piece portion 24 protruding from the inner surface of the vertical portion. In contact.
[0029]
Therefore, each secondary ventilation port 25 is closed by the damper 40 except for the state where the guide ventilation port 43 of the damper 40 is opposed to the secondary ventilation port 25 of the vertical portion 20a.
The blower mechanism 30 includes a casing 33 in which a suction port 31 is formed on a side surface on the damper 40 side and a rectangular blowout port body 32 protrudes in the circumferential direction, and a fan attached to the side surface of the casing facing the suction port 31. It comprises a motor 34 and a fan 35 attached to the rotation shaft of the fan motor.
[0030]
The fan 35 is a so-called sirocco fan type that sucks air from the axial direction along with rotation and blows air in the circumferential direction. Accordingly, the fan 35 functions to suck air from the suction port 31 of the casing 33 and blow air from the blower port body 32.
Since the blower mechanism 30 is attached to the vertical portion 20a of the unit base 20 via the damper 40 and the damper drive mechanism 45, there is a gap between the blower mechanism 30 and the vertical portion 20a.
[0031]
Further, the peripheral surface of the blower mechanism 30 is attached to the inclined portion 20b and the horizontal portion 20c of the unit base 20 with a gap therebetween, and in particular, the gap at the triangular protrusion of the unit base 20 is large.
As shown in FIG. 3 again, a drain draining nipple 50 and a ventilation nipple 51 are integrally projected at the left end of the front drain pan 16a so as to be aligned in a front view. The ventilation nipple 51 has a larger diameter than the drain drain nipple 50, and the nipples 50 and 51 are set at the same inclination angle.
[0032]
The ventilation outlet 15 of the ventilation unit 15 is inserted into the ventilation nipple 51, and a discharge hose (not shown) is connected to the outer peripheral surface of the nipple 51. A drain hose (not shown) is connected to the drain nipple 50, and each hose extends to the outside.
The air conditioner indoor unit configured as described above, when the operation switch of the remote control is turned on, the movable panel 2a which forms a part of the front panel 2 opens the front suction port 4, and the cooling operation The blowout louvers 8a and 8b provided in the blowout opening 9 are rotated according to the designation of the heating operation and the posture thereof is set.
[0033]
At the same time, the indoor blower 13 performs a blowing action, while the compressor of the outdoor unit is driven to start the refrigeration cycle operation. Indoor air is guided into the indoor unit body 1 from the upper suction port 6 and the front suction port 4 and passes through the air filter 11.
Most of the dust contained in the room air is captured by the air filter 11 and passes through the heat exchanger 10 in a state where the dust is removed, and a heat exchange action is performed. This heat exchange air is guided along the blowout ventilation path 18, guided from the blowout opening 9 to the blowout louvers 8a and 8b and blown into the room, and the efficient air conditioning operation is continued.
[0034]
Further, by causing the electrostatic precipitator 12 to function, fine dust that has passed through the air filter 11 is completely captured, and purified air is blown into the room through the heat exchanger 10 from the outlet 9.
Next, the operation of the ventilation unit 15 will be described.
The ventilation unit 15 can be switched to three types of modes: “secondary air ventilation mode”, “primary side air ventilation mode”, and “ventilation damper fully closed mode”.
[0035]
Here, the designation of the secondary side and the primary side is based on the heat exchanger 10 here, and the secondary side air means the air after flowing through the heat exchanger 10, and the primary side air is heat exchange. The air before flowing through the vessel 10.
FIGS. 9-11 has shown the inside of the ventilation unit 15 which removed the ventilation mechanism 30, and is a figure for demonstrating the state of the damper 40 corresponding to each mode. FIGS. 12-14 is a figure typically shown for demonstrating the state of the wind corresponding to each mode in the indoor unit main body 1. FIG.
[0036]
When the clean operation mode is selected at the end of the air conditioning operation, the “secondary air ventilation mode” functions automatically.
As shown in FIG. 9, the damper drive mechanism 45 of the ventilation unit 15 operates to rotate the damper 40. When the guide ventilation port 43 of the damper 40 reaches a position facing the secondary ventilation port 25 of the unit base 20, the rotation of the damper is stopped. This state is also shown in FIG.
[0037]
Next, the air blowing mechanism 30 of the ventilation unit 15 is activated, and air is sucked into the ventilation unit through the secondary ventilation port 25 and the guide ventilation port 43 and blown out from the blowout port body 32 through the air blowing mechanism.
While the indoor blower 13 is operated at an extremely low speed, the movable panel 2a closes the front suction port 4, the upper blowing louver 8a opens the blowing port 9 small, and the lower blowing louver 8b is closed. Made.
[0038]
Usually, in a state immediately after the cooling operation or the dehumidifying operation is stopped, moisture (drain water) is attached to the heat exchanger 10, and the interior of the indoor unit body 1 is in a high humidity atmosphere. If left as it is, moisture adhering to the heat exchanger 10 and other components does not evaporate, causing corrosion or mold.
Therefore, the above-described cleaning operation mode is selected, and the indoor unit body 1 is dried and sterilized.
Specifically, a small amount of room air is sucked into the indoor unit body 1 from the upper suction port 6, passes through the heat exchanger 10, and comes into contact with other components. Therefore, moisture present between the fin surfaces of the heat exchanger 10 and other component parts is evaporated.
[0039]
The air containing the evaporative moisture after passing through the heat exchanger 10, that is, the secondary air is sucked into the ventilation unit 15 and blown out from the outlet 32 as schematically shown in FIG. Is actually discharged outdoors. By exhausting the air containing the evaporating moisture directly to the outside, not only the heat exchanger 10 but also the interior of the indoor unit body 1 is quickly and completely dried to prevent the occurrence of mold and the like.
More specifically, as indicated by a dashed line arrow in FIG. 5, the secondary air passes through the gap between the outer surface of the inclined portion 20 b of the unit base 20 and the heat exchanger 10, and the outer surface of the vertical portion 20 a and the end surface of the cross flow fan 13 </ b> F. Led during.
[0040]
The secondary side air is sucked into the inside from the suction port 31 of the casing 33 through the secondary ventilation port 25 and the guide ventilation port 43 facing each other, and is blown out from the blowout port body 32.
In this way, the first suction guide portion Sa that sucks and guides the air in the indoor unit body 1 is formed in the ventilation unit 15 in accordance with the position of the damper 40. On the other hand, the said blowing outlet body 32 becomes a blowing guide part which carries out blowing guidance from the ventilation unit 15 to the outdoors.
[0041]
The electric dust collector 12 is energized after the above operation is continued for a predetermined time. The ozone generated in the electric dust collector 12 fills the indoor unit body 1 and is carried by a small amount of room air sucked from the upper suction port 6.
The room air containing ozone passes through the heat exchanger 10, contacts other components, is sterilized, and cuts off the odor source. The air after sterilizing the interior of the indoor unit main body 1 is guided to the first suction guide part Sa of the ventilation unit 15 and further discharged from the blowing guide part (blowing port body) 32 to the outside.
[0042]
In addition, since the electrostatic precipitator 12 is disposed at a position shifted toward the right end portion of the heat exchanger 10 and the ventilation unit 15 is disposed at the left end portion of the heat exchanger 10, ozone generated by the electrostatic precipitator 12 is removed from the indoor unit. The main body 1 is filled and can be ventilated after the entire body is spread, and the main body 1 is efficiently sterilized.
After the predetermined time has elapsed, when the function of the electric dust collector 12 is stopped and the operation of the indoor blower 13 is continued to some extent, the function of the ventilation unit 15 is also stopped and all the cleaning operation modes are ended.
Eventually, by selecting this cleaning operation mode, the indoor unit body 1 is sterilized and cleaned, and the air used here is directly discharged to the outside through the ventilation unit 15. Therefore, there is no influence on the environment for the room.
[0043]
As shown in FIG. 12 again, during the operation in the clean operation mode, only the upper blowout louver 8a is slightly opened and the indoor blower 13 is operated at a very low speed, so that after passing through the interior of the indoor unit body 1 Part of the air is blown out from the blowing louver 8a.
The blown wind is guided along the front panel 2 and is sucked into the upper suction port 6 again. Accordingly, a so-called short circuit wind is formed between the blowout port 9 and the upper suction port 6 in the indoor unit main body 1, which helps clean and sterilize the front panel 2 including the movable panel 2a.
[0044]
Next, when the ventilation mode provided in the remote controller is selected, the “primary air ventilation mode” is automatically performed. The ventilation mode may be selected in parallel with the air conditioning operation, or may be selected when the air conditioning operation is stopped.
That is, the ventilation mode is selected when it is desired to ventilate the room while cooling or heating. Alternatively, for example, when the hot air is in a room that has been closed when going out in the summer and the room temperature is lowered immediately after returning home to suppress the cooling load, only the ventilation mode may be selected.
[0045]
The indoor blower 13 rotates in accordance with the selection mode of the air conditioning operation regardless of the selection of the ventilation mode. Alternatively, stop only when ventilation operation is performed. The electrostatic precipitator 12 is also turned on according to the air-conditioning operation selection mode, turned on when the clean operation mode is selected, and turned off when the ventilation mode is selected.
The movable panel 2a and the blowout louvers 8a and 8b are also opened and closed in accordance with the operation mode during the air conditioning operation, and are closed only when the air conditioning operation is stopped and only in the ventilation operation. Since the upper suction port 6 is always open, room air is sucked into the indoor unit body 1 even in the case of only the ventilation operation.
[0046]
FIG. 10 shows the internal state of the ventilation unit 15 when the ventilation mode is selected.
The damper drive mechanism 45 rotationally drives the damper 40, and the damper drive mechanism 45 stops operating when the damper guide vent 43 is displaced to a position not facing the secondary vent 25 of the unit base 20.
The surface of the damper 40 comes into contact with the edge of the full closing piece 24 of the unit base 20, and the secondary ventilation opening 25 is closed by the damper. On the other hand, a gap is formed between the circumferential surface of the blower mechanism 30 and each inner surface of the unit base 20 with respect to the side surface of the damper 40, and the guide vent 43 communicates with these gaps.
[0047]
FIG. 13 schematically shows the air flow when the ventilation mode is selected after the air-conditioning operation is stopped.
The ventilation mechanism 30 of the ventilation unit 15 is activated, and the room air is sucked into the indoor unit body 1 from the upper suction port 6 that is always open. The room air passes through the air filter 11, captures dust, and then is directly guided to the ventilation unit 15 as primary air before passing through the heat exchanger 10, and is discharged from the outlet body 32 to the outside.
[0048]
If it demonstrates, the indoor air inhaled in the indoor unit main body 1 will be guide | induced as shown to the solid line arrow direction in FIG.
That is, since the air conditioning operation is stopped, the indoor blower 13 is also stopped. On the other hand, since the ventilation mechanism 30 of the ventilation unit 15 is operating, the primary air is collected from the space between the air filter 11 and the front surface of the heat exchanger 10 to the left end where the ventilation unit is disposed.
[0049]
And it is guide | induced to the ventilation unit 15 from between the heat exchanger 10 side surface and the side plate 1a of the indoor unit main body 1. FIG. As described above, a gap is formed between the unit base 20 and the casing 33 of the blower mechanism 30, a gap is formed between the unit base and the damper 40, and the guide vent 43 is opened. ing.
In this manner, the ventilation unit 15 is provided with the second suction guide portion Sb including these gaps depending on the position of the damper 40, and the indoor air is supplied to the ventilation unit 15 via the second suction guide portion. It is sucked in and discharged from the outlet 32.
[0050]
Eventually, the dirty air in the room is once sucked into the indoor unit main body 1, and after passing through the filter 11 by the action of the ventilation unit 15, before being led to the heat exchanger 10, it goes to the outside through the ventilation unit 15. Discharged. Since the dirty air does not pass through the heat exchanger 10, the ventilation effect is achieved while minimizing the contamination of the heat exchanger.
The above is the ventilation operation in a state where the air conditioning operation is stopped, but there is no problem even if the ventilation operation is performed after the air conditioning operation is continued. Also in this case, since the primary side air that does not pass through the heat exchanger 10 is collected and ventilated outdoors, an energy-saving operation that minimizes the energy loss due to the air-conditioning operation is possible.
[0051]
The ventilation unit 15 is in direct communication with the outdoors via a hose connected to the ventilation nipple 51. If an extremely large amount of dust is filled outdoors or there is a great amount of noise at night, it can be considered that these enter the ventilation unit 15 through the hose and further leak into the room through the indoor unit body 1.
If you do not want to operate the ventilation mode with the ventilation unit 15 fully closed as necessary, such as the installation environment condition or the use environment condition, select the above-mentioned “ventilation damper fully closed mode” to remove dust. And prevent the intrusion of noise.
[0052]
FIG. 11 shows the state of the damper 40 when the ventilation damper fully closed mode is selected. That is, the damper drive mechanism 45 rotates the damper 40, and the damper is rotated at a position where the crosspiece n between the guide ventilation ports 43 faces the edge of the full closing piece 24 of the unit base vertical portion 20a. To stop.
All of the guide ventilation ports 43 are surrounded by the full-closing piece 24 and the ribs 21 of the unit base 20 and are completely closed. Further, the secondary ventilation port 25 of the unit base 20 is completely closed by the damper 40 surface.
[0053]
Therefore, as schematically shown in FIG. 14, the ventilation unit 15 is completely closed by the damper 40 and the wind passage is blocked. Through the ventilation unit 15, it is possible to reliably prevent outdoor dust, noise, and the like (shown by broken arrows in the figure) from entering the indoor unit body 1 and the room, thereby improving comfort.
The ventilation unit 15 is inevitably set to be in the above-described state after the normal air-conditioning operation is completed as well as after the above-described main body cleaning operation mode is completed. In addition, if this mode is selected during the air-conditioning operation, a state equivalent to the normal air-conditioning operation is obtained.
[0054]
As described above, the ventilation unit can be switched so as to suck in and discharge the primary side air after passing through the air filter and before passing through the heat exchanger, to the outside. By having the drive mechanism, heat loss of the heat exchanger can be suppressed, and efficient indoor ventilation operation can be performed.
Furthermore, the damper drive mechanism of the ventilation unit can be switched to a fully closed mode that blocks the discharge path to the outside according to environmental conditions, etc., and blocks the flow between the interior of the indoor unit main body and the outdoors. By blocking the circulation between the inside of the machine body and the outside, it is possible to prevent the entry of dust, noise, etc. from the outside, and to switch to the same configuration as a normal air conditioner.
[0055]
In addition, the drive gear and at least two small gears are meshed with the damper and driven to rotate while guiding the outer periphery of the damper, so that sliding resistance is small and smooth rotation of the damper is guaranteed. it can.
[0056]
【The invention's effect】
As described above, according to the present invention, in addition to providing the original air conditioning function, moisture attached to the heat exchanger or the like after exhausting the cooling operation or the dehumidifying operation is completely discharged to the outside such as mold. There are effects such as suppressing the occurrence and increasing the cleanliness of the main body.
[Brief description of the drawings]
FIG. 1 is an external perspective view of an indoor unit of an air conditioner according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view of the indoor unit showing the embodiment.
FIG. 3 is a perspective view of the indoor unit with the front panel opened according to the embodiment;
FIG. 4 is a view for explaining different arrangements of indoor fans with respect to the heat exchanger, showing the embodiment;
FIG. 5 is a cross-sectional view of the ventilation unit and its peripheral portion showing the embodiment.
FIG. 6 is an exploded perspective view of the ventilation unit showing the embodiment;
FIG. 7 is a perspective view of one side of the ventilation unit showing the embodiment;
FIG. 8 is a perspective view of the other side of the ventilation unit showing the embodiment;
FIG. 9 is a front view showing the inside of the ventilation unit when the secondary air ventilation mode is selected, showing the embodiment;
FIG. 10 is a front view showing the inside of the ventilation unit when the primary air ventilation mode is selected, showing the embodiment;
FIG. 11 is a front view of the inside of the ventilation unit when the ventilation damper fully closed mode is selected, showing the embodiment;
FIG. 12 is a view for explaining the internal state of the ventilation unit when the secondary air ventilation mode is selected, showing the embodiment;
FIG. 13 is a view for explaining the internal state of the ventilation unit when the primary air ventilation mode is selected, showing the embodiment;
FIG. 14 is a view for explaining the state of the inside of the ventilation unit when the ventilation damper fully closed mode is selected, showing the embodiment;
[Explanation of symbols]
4 ... Front suction port,
6 ... Upper suction port,
9 ... the outlet,
1 ... indoor unit body,
10 ... heat exchanger,
13 ... Indoor fan,
11 ... Air filter,
15 ... Ventilation unit,
45 ... Damper drive mechanism,
42 ... gear part,
40 ... Damper,
47. Driving motor,
48 ... drive gear,
46: Small gear.

Claims (1)

An indoor unit main body equipped with a suction port at the front and upper part, and an outlet at the lower part of the front surface,
A heat exchanger accommodated in the indoor unit main body, disposed opposite to the front suction port and the upper suction port, and formed in a substantially inverted V shape in a side view ;
An indoor blower that is located inside the heat exchanger, sucks room air from the front suction port and the upper suction port , passes through the heat exchanger, and blows out from the blowout port,
An air filter attached between the heat exchanger and the front suction port and the upper suction port to capture and remove dust in the indoor air;
A unit base that is installed inside one side of the heat exchanger, forms one side surface and matches the shape of the heat exchanger, an air blowing mechanism that forms the other side surface, and these unit base and air blowing mechanism. A damper provided with a gear portion along the outer peripheral edge, a drive motor, a drive gear coupled to a rotating shaft of the drive motor, and at least two small gears. A ventilation unit comprising a damper drive mechanism meshing with the part,
The ventilation unit includes a primary-side air ventilation mode that sucks in and discharges the primary-side air before being guided to the heat exchanger after passing through the air filter and collecting dust, and a heat exchanger. Secondary air ventilation mode that sucks in the secondary side air after distribution and discharges it to the outside, and ventilation that blocks the discharge path to the outside according to environmental conditions etc. and blocks the distribution between the interior of the indoor unit body and the outside An indoor unit of an air conditioner characterized in that it can be switched to a damper fully closed mode .

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