JP2004069110A - Indoor unit of air conditioner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an indoor unit of an air conditioner equipped with an original air conditioning function, and a ventilation function for improving comfort, and avoiding an increase in body external dimensions and noise due to the improvement of comfort. <P>SOLUTION: A heat exchanger 10 and an indoor blower 13 are accommodated in the indoor unit body 1, where a front side heat exchanger section 10A facing a front inlet 4 and a rear side heat exchanger section 10B facing an upper inlet 6 are set to an inverse V shape in the side view. An air filter 11 is installed between the heat exchanger and the front /upper inlets. The indoor machine is equipped with a ventilation unit 15 comprising: first and second suction guidance sections Sa, Sb arranged at one side end section of the heat exchanger and at the inside of the inverse V shape, and opened to the inside of the indoor machine body; and an outlet body 32 opened to the outdoors and a blowing mechanism 30. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an air conditioner including an indoor unit and an outdoor unit, and more particularly, to an addition of an indoor ventilation function in an indoor unit.
[0002]
[Prior art]
An air conditioner including an indoor unit and an outdoor unit is frequently used. In the indoor unit, a main body is provided with a suction port and a blowout port, and a heat exchanger, a blower, and the like are housed inside the main body. An air filter is mounted on a front surface of the heat exchanger so as to capture dust before being guided to the heat exchanger.
By the way, not only does the user always perform indoor air conditioning, but also, depending on the situation, there is a case where it is desired to effectively and quickly perform indoor ventilation without opening windows.
[0003]
For example, in the living room, there is an unpleasant sensation such as a smoke full or unpleasant smell caused by multiple people smoking at the same time, but when the windows are opened, external noise and dust etc. enter. And the like.
Usually, a ventilation fan is provided in a kitchen or the like, but a ventilation fan dedicated to a living room is rarely provided. Therefore, in the case described above, it is necessary to cope with the situation by opening the window even slightly, or by standing without opening the window, and in any case, the comfort is impaired.
[0004]
[Problems to be solved by the invention]
Therefore, products have been provided in which the indoor unit main body is extended laterally long and a ventilation fan is provided at a position adjacent to the heat exchanger. Ventilation openings are opened in the front and rear sides of the indoor unit main body at locations facing the ventilation fan and at the mounting wall portion, and the ventilation fan is operated to exhaust indoor air to the outside.
With such an indoor unit, a ventilation function is obtained for the time being. However, since the ventilation fan is housed in the indoor unit main body in a state of being juxtaposed beside the heat exchanger, the external dimensions of the indoor unit main body And the mounting space increases.
[0005]
In addition, when the ventilation fan is driven, the operation noise leaks into the room from the ventilation port on the front surface of the main body, which hinders quiet operation. Further, there is a problem that external noise enters the indoor unit main body through the ventilation port on the wall surface and leaks into the room to hinder quiet operation.
The present invention has been made in view of the above circumstances, and aims to improve the comfort by adding a ventilation function in addition to the original air conditioning function, and to improve the external dimensions of the main body associated therewith. It is an object of the present invention to provide an indoor unit of an air conditioner that suppresses an increase in noise and an increase in noise.
[0006]
[Means for Solving the Problems]
In order to satisfy the above object, the present invention provides an indoor unit body having a front / upper suction port and a blowout port at a lower front portion, wherein a front heat exchanger section facing the front suction port and an upper suction port are opposed to each other. A rear V-shaped heat exchanger consisting of a rear heat exchanger section and an indoor blower that sucks indoor air from each suction port, passes through the heat exchanger, and blows out from the outlet, is housed. An air filter that captures and removes dust is attached between each suction port, and a suction guide opening inside the indoor unit body inside one end of the heat exchanger, and a blowing guide opening and a blowing mechanism opening outside. And a ventilation unit composed of
[0007]
Further, the indoor blower includes a fan motor and a cross flow fan having one support shaft connected to the fan motor, and includes a bearing portion that supports the other support shaft of the cross flow fan on one side surface of the ventilation unit. Was.
Further, the suction guide section of the ventilation unit is opened to face between the air filter and the heat exchanger, and sucks air before passing through the air filter and capturing dust and before being guided to the heat exchanger. invite.
Further, an electric dust collector is arranged between the air filter and the heat exchanger in the indoor unit main body and on the side opposite to the ventilation unit.
[0008]
By adopting the means for solving such a problem, it is possible to switch between the ventilation operation linked to the air-conditioning operation such as cooling and heating and the ventilation operation after the air-conditioning operation is stopped, thereby improving the comfort. .
In addition, it is possible to suppress an increase in the outer dimensions of the indoor unit main body due to the provision of the ventilation function, and to suppress an increase in indoor noise.
[0009]
Further, the ventilation unit can also serve as a bearing component of the cross flow fan constituting the indoor blower, and the number of components and the cost of components can be reduced.
Furthermore, the amount of dust adhering to the heat exchanger can be reduced, and the ozone generated by the electric dust collector can be entirely guided into the indoor unit main body to prevent generation of mold and the like.
[0010]
BEST MODE FOR CARRYING OUT 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 an air conditioner, FIG. 2 is a schematic longitudinal sectional view of the indoor unit, and FIG. 3 is a perspective view showing the inside of the indoor unit with a front panel removed. is there.
[0011]
The indoor unit main body 1 includes a front panel 2 and a rear panel 3, and has a horizontally long shape whose width direction is extremely long in the vertical direction. The front panel 2 is curved and protrudes to the near side, and has side plates 1a on both left and right sides. The rear plate 3 has a horizontally long rectangular shape and is attached to a wall surface of the room to be air-conditioned.
A front suction port 4 is opened in a part of the front side of the front panel 2, and a movable panel 2a 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, at the time of driving, the movable panel 2a is controlled to project toward the front side and open the front suction port 4.
[0012]
An upper suction port 6 is provided over the front panel 2 and the rear plate 3. A frame-shaped bar 7 is fitted into the upper suction port 6, and is partitioned into a plurality of spaces by the bar.
Below the movable panel 2a, a decorative plate 2b made of a translucent material constituting a part of the front panel 2 is provided across the width of the indoor unit main body 1. Below the decorative plate 2b, two blowout louvers 8a and 8b are provided in parallel.
[0013]
Each of the blowout louvers 8a and 8b opens and closes a blowout port 9 provided along a lower portion of the front surface of the indoor unit main body 1, and can change a posture angle in accordance with operating conditions to set a blowout direction of 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 section 10A and a rear heat exchanger section 10B is arranged. The front heat exchanger section 10A is formed in a curved shape that is substantially parallel to the front panel 2 with a gap therebetween, and the rear heat exchanger section 10B is formed in a straight shape and is obliquely inclined with the upper suction port 6. And face each other.
[0014]
On the other hand, an air filter 11 is mounted in the indoor unit main 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 10A and the upper heat exchanger section 10B, and is detachably provided between the open upper end of the outlet 9 and the lower end of the front panel 2. It is inserted.
An electric precipitator 12 is mounted on 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 main body 1. The electrostatic precipitator 12 includes a charging-side electrode that applies electric charges to dust in the flowing air, and a dust-collecting electrode that attracts and captures the charged dust.
[0015]
The electric precipitator 12 is an ozone generator that generates a large amount of ozone when a high voltage is applied to the charging-side electrode so that the potential difference between the precipitating-side electrode and the precipitating-side electrode becomes larger than during normal dust collection. At this time, by stopping or operating the blower 13 at a very low speed in order to restrict the flow of the surrounding air, the amount of generated ozone becomes larger.
An indoor blower 13 is arranged between the front and rear heat exchanger portions 10A and 10B of the heat exchanger 10 and between the heat exchanger 10 and the outlet 9. That is, the indoor blower 13 is located inside the umbrella-shaped heat exchanger 10.
[0016]
As shown schematically in FIG. 4A, the indoor blower 13 includes a fan motor 13M and a transverse fan 13F in which one support shaft a is mechanically connected to a rotation shaft of the fan motor. You.
The axial length La of the cross flow fan 13F is substantially the same as the width dimension L of the heat exchanger 10, and is provided on the right side of the heat exchanger 10 as a whole as viewed from the front.
[0017]
That is, the left end c of the cross flow fan 13F is located inside 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 L of the heat exchanger 10 is provided, and the left end c of the fan is the same as that of FIG. 4A. Although positioned, the right end g may be aligned with the right side f of the heat exchanger 10.
[0018]
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 disposed in a space next to the indoor blower 13 formed by shifting the position of the indoor blower 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 is mounted inside the umbrella-shaped heat exchanger 10 together with the indoor blower 13. .
[0019]
As shown in FIG. 2 again, the lower end of the front heat exchanger unit 10A rests on the front drain pan 16a, and the lower end of the rear heat exchanger unit 10B rests on the rear drain pan 16b. Drain water dropped from the parts 10A and 10B can be received and drained to the outside via a drain hose (not shown).
Further, the outer surfaces of the side walls of the front and rear drain pans 16a and 16b are provided at positions close to the indoor blower 13, and these constitute a nose of the indoor blower 13 with respect to the cross flow fan 13F.
[0020]
A partition wall member 17 connects between the side wall portions of the front and rear drain pans 16 a and 16 b constituting the nose and each side of the outlet 9. The space surrounded by the partition member 17 is a blow ventilation passage 18 that communicates the nose with the blow opening 9.
Next, the ventilation unit 15 will be described in detail.
5 is a cross-sectional view of the ventilation unit 15 and a view for explaining the arrangement of other components. FIG. 6 is an exploded perspective view of the ventilation unit. 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.
[0021]
The ventilation unit 15 includes a unit base 20 forming one side surface thereof, a blowing mechanism 30 forming the other side surface, a damper 40 and a damper drive provided between the unit base 20 and the blowing mechanism 30. And a mechanism 45.
The unit base 20 includes a vertical portion 20a, a slanted portion 20b is formed along an edge excluding a lower end edge of the vertical portion, and the unit base 20 is horizontally bent integrally from the edge of the slanted portion. The unit 20c is provided.
[0022]
The upper portion of the vertical portion 20a is formed to project substantially in a triangular shape in a side view, and has an umbrella-like combination shape of a front heat exchanger portion 10A and a rear heat exchanger portion 10B constituting the heat exchanger 10. Agree.
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 here, and the fin F constituting the heat exchanger 10 is placed on the horizontal portion 20c. . When the heat exchanger 10 is mounted on the horizontal portion 20c, a gap is formed at a portion facing the inclined portion 20b.
[0023]
A circular mounting opening 21 is opened substantially at the center of the vertical portion 20a, and a rib 22 is provided along the peripheral surface of the opening and bent toward the inner surface of the vertical portion 20a. Reinforcing ribs 23 are provided radially on the outer surface of the vertical portion 20a along the periphery of the mounting opening 21.
On the inner surface side of the vertical portion 20a, a plurality (seven) of full-closing pieces 24 are provided along a substantially half circumference of the opening 21 at predetermined intervals. Half of the full-closing pieces 24 among these full-closing pieces 24 are open to each other, and this opening is referred to as a secondary ventilation port 25. That is, three secondary ventilation ports 25 are provided.
[0024]
A bearing 26 is fitted and fixed in the mounting opening 22 of the vertical portion 20a, and a bearing 27 is formed by these. As described above, the bearing portion 27 supports the other (left side) support shaft h of the cross flow fan 13F constituting the indoor blower 13.
On the inner surface side of the vertical portion 20a, two stays 28a protrude on the same radius of curvature. These stays 28a are formed to have a small diameter only at the protruding ends, and small gears 46 constituting the damper drive mechanism 45 are rotatably fitted into the stays 28a, respectively, and are prevented from falling off by appropriate means.
[0025]
A plurality of stays 28b having a height higher than the stay 28b are provided near the stay 28a. A screw hole is provided in the axial direction from the protruding end face of each stay 28b, and a mounting screw m for mounting and fixing the blower mechanism 30 is inserted.
Only the stay 28b provided near the fully closed piece 24 has a receiving portion 29 integrally provided adjacent to the peripheral portion. A drive motor 47 constituting a damper drive mechanism 45 is attached and fixed to the receiving portion 29, and a drive gear 48 connected to a rotation shaft of the drive motor is rotatably supported.
[0026]
On the other hand, a fitting portion 41 provided at the center of the damper 40 is rotatably fitted on the outer peripheral surface of the rib 21 constituting the bearing portion 27. The damper 40 has 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 section 42 of the damper 40 is assembled so that the two small gears 46 and the driving gear 48 described above mesh with each other. Therefore, the damper 40 is rotated by the drive motor 47 rotating the drive gear 48, and the small gear 46 functions as an idle gear with respect to the damper gear portion 42.
[0027]
Further, between the fitting portion 41 and the outer peripheral gear portion 42 of the damper 40, a plurality (three) of guide ventilation holes 43 are provided in a part in the circumferential direction. These guide ventilation holes 43 have exactly the same opening dimensions and shape as the secondary ventilation holes 25 provided in the unit base vertical portion 20a.
The cross sections n formed between the guide ventilation ports 43 have exactly the same interval as the mutual intervals of the fully-closed pieces 24. The damper 40 has a gap with the inner surface of the vertical portion 20a in a state of being fitted into the rib 21. In contact.
[0028]
Therefore, each secondary ventilation port 25 is closed by the damper 40 except that the guide ventilation port 43 of the damper 40 faces the secondary ventilation port 25 of the vertical portion 20a.
The blower mechanism 30 has a casing 33 in which a suction port 31 is formed on a side face on the damper 40 side and a rectangular outlet body 32 is projected in a circumferential direction, and a fan attached to a side face of the casing facing the suction port 31. It comprises a motor 34 and a fan 35 attached to the rotating shaft of the fan motor.
[0029]
The fan 35 is of a so-called sirocco fan type that sucks air from the axial direction and blows the air in the circumferential direction with the rotation. The fan 35 has a function of sucking air from the suction port 31 of the casing 33 and blowing air from the blowing 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.
[0030]
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 the gap at the triangular projection of the unit base 20 is particularly large.
As shown in FIG. 3 again, a drain nipple 50 and a ventilation nipple 51 are integrally provided 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 nipple 50, and the nipples 50 and 51 are set at the same inclination angle.
[0031]
The outlet 32 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 drain nipple 50, and each hose extends outside.
When the operation switch of the remote controller is turned on in the indoor unit of the air conditioner configured as described above, the movable panel 2a forming a part of the front panel 2 opens the front suction port 4 to perform the cooling operation. The blowout louvers 8a and 8b provided in the blowout opening 9 are rotated in accordance with the designation of the heating operation and the posture thereof is set.
[0032]
At the same time, while the indoor blower 13 performs a blowing action, the compressor of the outdoor unit is driven to start the refrigeration cycle operation. The indoor air is guided into the indoor unit main 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 indoor air is captured by the air filter 11 and passes through the heat exchanger 10 in a state where the dust has been removed to perform a heat exchange action. This heat exchange air is guided along the blow air passage 18 and is guided from the blow outlet 9 to the blow louvers 8a and 8b to be blown into the room, thereby continuing the efficient air conditioning operation.
[0033]
By causing the electric dust collector 12 to function, the fine dust that has passed through the air filter 11 is completely captured, and the purified air is blown into the room from the outlet 9 via the heat exchanger 10.
Next, the operation of the ventilation unit 15 will be described.
The ventilation unit 15 can be switched between three types of modes: a “secondary air ventilation mode”, a “primary air ventilation mode”, and a “ventilation damper fully closed mode”.
[0034]
The names of the secondary side and the primary side are based on the heat exchanger 10 herein, and the secondary side air is air after flowing through the heat exchanger 10, and the primary side air is a heat exchange Air before flowing through the vessel 10.
9 to 11 show the inside of the ventilation unit 15 from which the blower mechanism 30 is removed, and are views for explaining states of the damper 40 corresponding to each mode. FIG. 12 to FIG. 14 are diagrams schematically illustrating the state of the wind corresponding to each mode in the indoor unit main body 1.
[0035]
When the clean operation mode is selected at the end of the air conditioning operation, the “secondary air ventilation mode” automatically functions.
As shown in FIG. 9, the damper driving mechanism 45 of the ventilation unit 15 operates to rotate the damper 40. When the guide vent 43 of the damper 40 reaches a position facing the secondary vent 25 of the unit base 20, the rotation of the damper is stopped. This state is also shown in FIG.
[0036]
Next, the air blowing mechanism 30 of the ventilation unit 15 is operated, and air is sucked into the ventilation unit through the secondary ventilation port 25 and the guide ventilation port 43, and is blown out of the outlet 32 through the air blowing mechanism.
While the indoor blower 13 is operated at a very low speed, the movable panel 2a closes the front inlet 4, the upper outlet louver 8a opens the outlet 9 slightly, and the lower outlet louver 8b closes. Is done.
[0037]
Normally, immediately after the cooling operation or the dehumidifying operation is stopped, moisture (drain water) adheres to the heat exchanger 10, and the interior of the indoor unit main body 1 has a high humidity atmosphere. If left as it is, moisture adhering to other components such as the heat exchanger 10 does not evaporate, causing corrosion or mold.
Therefore, the above-mentioned clean operation mode is selected, and the drying and sterilization operation in the indoor unit main body 1 is performed.
Specifically, a small amount of indoor air is sucked into the indoor unit main body 1 from the upper suction port 6, passes through the heat exchanger 10, and comes into contact with other components. Therefore, moisture existing between the fin surfaces of the heat exchanger 10 and on other component parts surfaces evaporates.
[0038]
The air containing evaporative moisture after passing through the heat exchanger 10, that is, the secondary air, is sucked into the ventilation unit 15 as schematically shown in FIG. It is typically discharged outdoors. By directly discharging the air containing the evaporated moisture to the outside, not only the heat exchanger 10 but also the interior of the indoor unit main body 1 is completely dried quickly to prevent generation of mold and the like.
To further explain, as shown by a dashed line arrow in FIG. 5, the secondary side air passes through a gap between the outer surface of the inclined portion 20b of the unit base 20 and the heat exchanger 10, and flows between the outer surface of the vertical portion 20a and the end surface of the cross flow fan 13F. Guided between.
[0039]
Then, the secondary 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.
Thus, the first suction guide portion Sa for sucking and guiding the air in the indoor unit main body 1 is formed in the ventilation unit 15 according to the position of the damper 40. On the other hand, the outlet 32 serves as an outlet guide for guiding the air from the ventilation unit 15 to the outside.
[0040]
After the above operation is continued for a predetermined time, the electric dust collector 12 is energized. The ozone generated by the electric dust collector 12 fills the indoor unit main body 1 and is carried by a small amount of indoor air sucked from the upper suction port 6.
The room air containing ozone passes through the heat exchanger 10 and comes into contact with other components to sterilize it and cut off odors. The air after the inside of the indoor unit main body 1 is sterilized is guided to the first suction guide portion Sa of the ventilation unit 15, and is further discharged outside from the blow-out guide portion (blow-out opening) 32.
[0041]
In addition, since the electric dust collector 12 is arranged at a position shifted toward the right end of the heat exchanger 10 and the ventilation unit 15 is arranged at the left end of the heat exchanger 10, the ozone generated by the electric dust collector 12 is removed from the indoor unit. After filling the inside of the main body 1, the whole body can be ventilated, and the inside of the main body 1 can be efficiently sterilized.
After a lapse of a predetermined time, 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 clean operation modes are ended.
[0042]
After all, by selecting this clean operation mode, the interior of the indoor unit main body 1 is sterilized and purified, and the air used here is discharged outside through the ventilation unit 15. Therefore, there is no influence on the environment for the room.
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 an extremely low speed. Is partially blown out from the blowout louver 8a.
[0043]
The blown wind is guided along the front panel 2 and is sucked into the upper suction port 6 again. Therefore, a so-called short-circuit wind is formed between the outlet 9 and the upper inlet 6 in the indoor unit main body 1, which is useful for cleaning and sterilizing the front panel 2 including the movable panel 2a.
Next, when the ventilation mode provided on 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.
[0044]
That is, when it is desired to perform indoor ventilation while performing the cooling operation or the heating operation, the ventilation mode is selected. Alternatively, for example, when hot air is trapped in a room that is completely closed when going out in summer and the indoor temperature is to be lowered immediately after returning home to reduce the cooling load, only the ventilation mode may be selected.
The indoor blower 13 rotates according to the air-conditioning operation selection mode regardless of the selection of the ventilation mode. Alternatively, when only the ventilation operation is performed, the operation is stopped. The electric dust collector 12 is also turned on in accordance with the air conditioning operation selection mode, is turned on when the clean operation mode is selected, and is turned off when only the ventilation mode is set.
[0045]
The movable panel 2a and the blow-out louvers 8a and 8b also open and close according to the operation mode during the air-conditioning operation, and close when the air-conditioning operation is stopped and only in the ventilation operation. Since the upper suction port 6 is always open, the room air is sucked into the indoor unit main body 1 even when only the ventilation operation is performed.
FIG. 10 shows an internal state of the ventilation unit 15 when the ventilation mode is selected.
The damper drive mechanism 45 rotationally drives the damper 40, and when the guide ventilation port 43 of the damper is displaced to a position that does not face the secondary ventilation port 25 of the unit base 20, the damper drive mechanism 45 stops operating.
[0046]
The surface of the damper 40 contacts the edge of the fully closed piece 24 of the unit base 20, and the secondary ventilation port 25 is closed by the damper. On the other hand, gaps are formed between the peripheral surface of the blower mechanism 30 and the respective inner surfaces of the unit base 20 with respect to the side surfaces of the damper 40, and the guide ventilation holes 43 communicate with these gaps.
FIG. 13 schematically shows the flow of air when the ventilation mode is selected after stopping the air-conditioning operation.
The air blowing mechanism 30 of the ventilation unit 15 is operated, and indoor air is sucked into the indoor unit main body 1 from the upper suction port 6 which is always open. The indoor air is directly guided to the ventilation unit 15 as primary air before passing through the heat exchanger 10 after the dust is captured by passing through the air filter 11 and discharged from the outlet 32 to the outside.
[0047]
In addition, to explain, the indoor air sucked into the indoor unit main body 1 is guided as shown by a solid arrow direction in FIG.
That is, since the air conditioning operation is stopped, the indoor blower 13 is also in a stopped state. 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 at the left end where the ventilation unit is arranged.
[0048]
Then, the air is guided to the ventilation unit 15 from between the side surface of the heat exchanger 10 and the side plate 1 a of the indoor unit main body 1. 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 ventilation opening 43 is opened. ing.
In this manner, the ventilation unit 15 is formed with the second suction guide portion Sb formed by these gaps depending on the position of the damper 40, and the room air is supplied to the ventilation unit 15 through the second suction guide portion. And is discharged from the outlet body 32.
[0049]
After all, the dirty air in the room is once sucked into the indoor unit main body 1 and further passed through the filter 11 by the action of the ventilation unit 15 before being led to the heat exchanger 10 before going outside through the ventilation unit 15. Is discharged. Since the dirty air does not pass through the heat exchanger 10, a ventilating action that minimizes the contamination of the heat exchanger is provided.
The above is the ventilation operation in a state where the air-conditioning operation is stopped. However, 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 to the outside, the energy saving operation in which the energy loss due to the air conditioning operation is minimized is possible.
[0050]
The ventilation unit 15 is in direct communication with the outside through a hose connected to the ventilation nipple 51. If an extremely large amount of dust is filled outdoors or there is a loud noise at night, these may enter the ventilation unit 15 through a hose and leak into the room through the indoor unit body 1.
If it is not desired to make the ventilation unit 15 fully closed and to operate the ventilation mode as required, such as in the installation environment condition or the use environment condition, the above-mentioned “ventilation damper fully closed mode” is selected and the And stop the intrusion of noise.
[0051]
FIG. 11 shows the state of the damper 40 when the ventilation damper fully closed mode is selected. That is, the damper driving mechanism 45 rotates the damper 40, and the damper rotates at a position where the cross section n between the guide ventilation ports 43 faces the edge of the fully closed piece 24 of the unit base vertical portion 20a. To stop.
All the guide vents 43 are surrounded by the fully closed pieces 24 and the ribs 21 of the unit base 20 and are completely closed. Further, there is no change in that the secondary ventilation port 25 of the unit base 20 is completely closed by the surface of the damper 40.
[0052]
Therefore, as schematically shown in FIG. 14, the ventilation unit 15 is completely closed by the damper 40, and the air flow passage is shut off. Through the ventilation unit 15, intrusion of dust and noise from the outside into the indoor unit body 1 and the room can be reliably prevented, and the comfort can be improved.
It is to be noted that the ventilation unit 15 is set to be in the above-described state inevitably after the end of the normal air-conditioning operation as well as after the end of the in-body clean operation mode described above. Further, if this mode is selected during the air-conditioning operation, the state becomes the same as the normal air-conditioning operation.
[0053]
As described above, since the ventilation unit 15 is disposed inside the heat exchanger 10, the ventilation unit can be attached without increasing the size of the indoor unit body 1, thereby saving space and operating the ventilation unit 15. The generation of noise due to this can be minimized.
Furthermore, since the ventilation unit 15 includes the bearing 27 for one of the support shafts h of the cross flow fan 13F constituting the indoor blower 13, the number of required components is reduced, which contributes to a reduction in component costs.
[0054]
Further, since the second suction guide Sb formed by the position of the damper 40 is configured to suck the primary air before passing through the air filter 11 and guided to the heat exchanger 10, the dust suction exchanger 10 The amount of adhesion can be suppressed, and loss of heat exchange energy is suppressed to a minimum, for example, when performing ventilation operation in parallel with air-conditioning operation.
Furthermore, since the electric precipitator 12 and the ventilation unit 15 are arranged on the opposite sides, the ozone generated by the electric precipitator is filled in the indoor unit main body 1 and ventilation is performed after the ozone is entirely spread. And sterilization efficiency can be improved.
[0055]
【The invention's effect】
As described above, according to the present invention, in addition to the provision of the original air conditioning function, the ventilation function is added to improve the comfort, and thereby the external dimensions of the main body and the noise are increased. And the like.
[Brief description of the drawings]
FIG. 1 is an external perspective view of an indoor unit of an air conditioner, showing an embodiment of the present invention.
FIG. 2 is a sectional view of the indoor unit, showing the embodiment.
FIG. 3 is a perspective view showing the embodiment, in a state where a front panel of the indoor unit is opened.
FIG. 4 is a view showing the embodiment and illustrating different arrangements of the indoor blower with respect to the heat exchanger.
FIG. 5 is a cross-sectional view of the ventilation unit and its surroundings, 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 of the inside of the ventilation unit when the secondary air ventilation mode is selected, showing the embodiment;
FIG. 10 is a front view of 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 showing the same embodiment and is a diagram for explaining an internal state of the ventilation unit when a secondary air ventilation mode is selected.
FIG. 13 is a view for explaining the internal state of the ventilation unit when the primary air ventilation mode is selected according to the embodiment;
FIG. 14 is a view illustrating the state of the inside of the ventilation unit when the ventilation damper fully closed mode is selected according to the embodiment;
[Explanation of symbols]
4: Front suction port,
6 ... upper suction port,
9 ... outlet,
1 ... indoor unit body,
10A: Front heat exchanger section,
10B ... rear heat exchanger part,
10 ... heat exchanger,
13. Indoor blower,
11 ... air filter,
Sa, Sb: first and second suction guides,
32 ... Blow-out guide (Blow-out body)
30 ... Blower mechanism
15 ... ventilation unit.

Claims (4)

An indoor unit body having an inlet at the front and upper portions and an outlet at the lower front,
A front heat exchanger section accommodated in the indoor unit main body and arranged opposite to the front suction port and a rear heat exchanger section arranged opposite to the upper suction port are formed in a reverse view in a side view. A heat exchanger combined in a letter shape,
An indoor blower that sucks indoor air from the front / upper suction port and passes through the heat exchanger, and blows out from the outlet port;
An air filter attached between the heat exchanger and the front / upper suction port to capture and remove dust in room air,
One side end of the heat exchanger and the inside of the inverted V-shape, and a suction guide opening inside the indoor unit body, a blowout guide opening outside and the air suction from the suction guide. An air conditioner indoor unit, comprising: a ventilation unit that includes a blowing mechanism that blows air to the blowing guide section. The indoor blower includes a fan motor, and a cross flow fan having one support shaft connected to the fan motor,
The indoor unit for an air conditioner according to claim 1, further comprising a bearing portion on one side surface of the ventilation unit for supporting the other support shaft of the cross flow fan. The suction guide portion of the ventilation unit is opened opposite to the space between the air filter and the heat exchanger. The indoor unit of an air conditioner according to claim 1, wherein the primary air of the air conditioner is sucked and guided. The air conditioner according to claim 1, wherein an electric dust collector is disposed in the indoor unit main body between the air filter and the heat exchanger and on a side opposite to the ventilation unit. Indoor unit.

Images