KR20190096928A - Indoor unit of air conditioner - Google Patents

Abstract

The indoor unit of the air conditioner includes a suction port, a plurality of blowout ports provided to surround the periphery of the intake port, and a plurality of louvers provided at each of the blowout ports and configured to adjust the blowout direction. When the indoor unit is stopped, the louver is rotated in the direction of closing the outlet, and the angle of the louver at the time of stopping the indoor unit rotated in the direction of closing the outlet is set as a completely closed angle, and the louver is operated when the indoor unit is operated. And a remote controller for setting the operation of a plurality of the outlets during heating operation when a minimum angle of the louvers that can be set by the remote controller is a first angle and a maximum angle is a second angle. And the louver angle of some of the outlets is set to a third angle larger than the fully closed angle, which is the angle of the louver at the time of stopping the indoor unit, and smaller than the first angle, and the louvers of the other outlets are set to auto swing or downward ejection. do.

Description

Indoor unit of air conditioner

The present invention relates to an indoor unit of an air conditioner having a plurality of blowout ports and having a louver for controlling the wind direction of each blowout outlet, and is particularly suitable for an indoor unit of a four-way ceiling cassette type.

As an indoor unit of a conventional air conditioner, there is a ceiling cassette type which has a plurality of blowout ports (for example, four) and has a louver for controlling the wind direction of each blower outlet.

Usually, the louver in the indoor unit of the air conditioner is configured to be the wind direction set by the user with the remote control. However, under certain operating conditions, the indoor unit itself is configured to forcibly control the louver to change the wind direction. have. For example, at the time of heating start, when heating operation start control which warms a room quickly is performed, and when normal heating operation is performed, the control which improves the temperature nonuniformity of the upper part and the lower part of a room is performed.

As a prior art which performed the heating operation start control mentioned above, there exists a thing of Unexamined-Japanese-Patent No. 8-320145 (patent document 1). In the indoor unit (indoor unit) of the air conditioner described in this patent document 1, at the start of heating operation (at the time of heating operation start), the warm air is directly blown out in the indoor living space with the louver angle downward. Heat the room by convection heating. When the difference between the room temperature and the set temperature is within a predetermined value, the louver swings up and down, and after a predetermined time elapses, the wind direction of the blown air is controlled in a direction substantially parallel to the ceiling surface (horizontal blowout) to operate the radiant heating. The transition is described.

Thereby, it is described that the heating can be performed comfortably without causing the inhabitants of the room to feel warm air by radiant heat of warm air near the ceiling while effectively preventing the decrease in room temperature.

Moreover, as a prior art which made control to improve the temperature nonuniformity of the upper part and the lower part of a room at the time of normal heating operation, there exist some described in Unexamined-Japanese-Patent No. 2011-196666 (patent document 2). In what is described in this patent document 2, when it judges that it is a temperature nonuniformity, the temperature nonuniformity cancellation control part starts a swing operation of a louver, and stops a swing operation when predetermined | prescribed conditions are satisfied, and a louver moves a downward position after that. Controlling to adopt is described.

Japanese Patent Laid-Open No. 8-320145 Japanese Patent Laid-Open No. 2011-196666

In the patent document 1, when the heating starts, the room is heated by convection heating toward the downward direction, and when the difference between the room temperature and the set temperature is within a predetermined value, the louver is swinged up and down, and the vicinity of the ceiling and people Both sides near the bottom can be heated.

Further, in the patent document 2, when the temperature is in a non-uniform state, the swing operation of the louver is started, and when the predetermined condition is satisfied, the swing operation is stopped to control the louver to adopt a downward attitude, so as to reduce the temperature non-uniformity. Doing.

However, in the case of an indoor unit of an air conditioner having a plurality of outlets (for example, 4) so as to surround the inlet, all the outlets are moved downward when all the louvers are turned downward or all the louvers are swinged up and down during heating operation. The wind direction at the same time is a downward blow out occurs. If the wind direction of all the blowout ports is determined to be downward blown at the same time, there is a problem that the blowout air is sucked into the intake port before spreading to the indoor space, that is, a short circuit is likely to occur, and the heating capability is lowered.

In addition, a suction air temperature sensor is generally installed at the suction port. When a short circuit occurs, the blown air reaches the suction air temperature sensor so that the suction air temperature sensor detects a temperature higher than the actual indoor air temperature. There is also a problem that causes unnecessary heating stop (thermo-off).

Moreover, in the indoor unit provided with four blowout ports, by making the louver of some blowout outlets into the fully closed position (position at the time of stop of operation), the wind speed in the remaining blowout outlet is increased, and the up-down temperature difference is small (the temperature nonuniformity is small). Although the indoor environment is created, there is a problem that the louver breaks because the louver is placed in the fully closed position because the wind pressure of the hot air acts.

An object of the present invention is to obtain an indoor unit of an air conditioner that can suppress a short circuit and also prevent warpage of the louver.

In order to achieve the above object, the present invention provides an air conditioner having a suction port, a plurality of blowout ports provided to surround the periphery of the suction hole, and a plurality of louvers provided at each of the blowout ports and configured to adjust the blowout direction. In the indoor unit of the indoor unit, when the indoor unit is stopped, the louver is rotated in the direction of closing the outlet, and the louver angle at the time of stopping the indoor unit rotated in the direction of closing the outlet is set to the fully closed angle, the operation of the indoor unit When the heating operation is provided with a remote controller for setting the operation of the louver at the time, and the minimum angle of the louver settable by the remote control is the first angle and the maximum angle is the second angle, The angle of the louver of some of the outlets of the above-mentioned outlet is larger than the fully closed angle which is the angle of the louver at the time of the indoor unit stop. Also being set to a third angle than the first angle, the louver of the other air outlet is characterized in that it is set to automatic or swing downward extraction.

According to the present invention, there is an effect that an indoor unit of an air conditioner capable of suppressing short circuits and also preventing warpage of louvers can be obtained.

BRIEF DESCRIPTION OF THE DRAWINGS It is a perspective view which shows Example 1 of the indoor unit of the air conditioner of this invention.
FIG. 2 is a longitudinal cross-sectional view of the indoor unit shown in FIG. 1. FIG.
FIG. 3 is a cross-sectional view of one main part of the blowout ports shown in FIGS. 1 and 2, and the louver is in a completely closed state. FIG.
Fig. 4 is a cross-sectional view of one main part of the ejection ports shown in Figs. 1 and 2 and shows a minimum angle (first angle) and a maximum angle (second angle) of the louver during indoor unit operation.
FIG. 5: is sectional drawing of the principal part of the blowout port shown in FIG. 1, FIG. 2, and is a figure explaining the 3rd angle of the louver in this Embodiment 1. FIG.
It is a figure explaining the operation | movement in the state in which the louver shown in FIG. 5 is a 3rd angle.
It is a figure explaining the louver operation | movement at the time of the starting operation in the indoor unit of the conventional air conditioner, and the stirring operation after that.
FIG. 8: is a figure explaining the short circuit phenomenon in the case where all louvers are taken out downward at the time of a starting operation, and the stirring operation after that.
It is a figure explaining the louver operation | movement at the time of the starting operation in Example 1 of the indoor unit of an air conditioner, and the stirring operation after that.
It is a figure explaining the louver operation | movement at the time of the stirring operation shown in FIG. 9, the flow of extraction air, and the flow of intake air.
It is a figure explaining the louver operation | movement at the time of the starting operation in the Example 2 of the indoor unit of an air conditioner, and the stirring operation after that.
It is a figure explaining the louver operation | movement at the time of the starting operation in the Example 3 of the indoor unit of the air conditioner, and the stirring operation after that.

Hereinafter, specific embodiments of the present invention will be described based on the drawings. In each figure, the same code | symbol has shown the same or corresponding part.

Example 1

Embodiment 1 of the indoor unit of the air conditioner of this invention is demonstrated using FIGS.

First, the whole structure of the indoor unit of the air conditioner in Example 1 is demonstrated using FIG. 1 is a perspective view showing an indoor unit of the air conditioner of the first embodiment.

As shown in Fig. 1, the indoor unit 1 of the air conditioner is connected to an outdoor unit (not shown) by a refrigerant pipe to form a refrigerant circuit, and the refrigerant is circulated to form a refrigeration cycle. The indoor unit 1 is a so-called ceiling cassette type, and includes a housing 2 embedded in a ceiling of a room, a makeup panel 3 provided to block an opening of a lower surface of the housing 2, and the like. ) Is provided in the center, and has an intake port 4 for sucking indoor air and an air outlet 5 for four places provided to surround the intake port 4.

A suction grill 6 is provided at the suction port 4, and a louver 7 for adjusting the blowout direction of the air blown out from the blowout outlet 5 is provided at each blowout outlet 5, respectively. have. In addition, the louver 7 shown in FIG. 1 has shown the state in which the indoor unit 1 was stopped and fully closed, ie, the state in which a louver angle is a fully closed angle (0 degree). The completely closed includes not only a state in which the outlet 5 is completely closed, but also a state in which the louver is almost horizontal and the opening area is minimized so as to almost block the outlet.

FIG. 2 is a longitudinal sectional view of the indoor unit 1 shown in FIG. 1. As shown in FIG. 2, the motor 8 and the centrifugal fan 9 connected to the rotating shaft of this motor 8 are provided in the center part in the said housing 2. As shown in FIG. The motor 8 is fixed to the center of the ceiling plate of the housing 2.

In addition, a spherical heat exchanger 10 is provided around the centrifugal fan 9 so as to surround the centrifugal fan 9. This heat exchanger 10 is a cross fin fin and tube heat exchanger. Further, a drain pan 11 for receiving condensation water generated in the heat exchanger 10 is provided below the heat exchanger 10. As this drain pan 11, the heat insulating material made of foamed styrol is generally used, and the drip tray groove | channel along the lower end of the said heat exchanger 10 is formed, and the lower end part of the said heat exchanger 10 enters this drip groove. In addition, although not shown in figure, the blowout opening 5 is formed by the heat insulating material which comprises the said drain pan 11 integrally, or a separate heat insulating material.

20 is a ceiling of the room, and the indoor unit 1 is provided with a part of the housing 2 embedded in the ceiling 20. The makeup panel 3 is formed in a square shape larger than that of the housing 2, is disposed along the ceiling 20 so as to cover the lower surface of the housing 2, and is exposed to an interior space.

The louver 7 provided in the ejection opening 5 of the cosmetic panel 3 is in the fully closed position (the louver angle is 0 degrees) in FIG. 2, and shows the state in which the operation of the indoor unit 1 is stopped. have. When the indoor unit 1 starts to operate, the louver 7 is rotated so as to open the outlet 5, and predetermined by the user from a remote controller (not shown), such as downward ejection or horizontal ejection (horizontal ejection). Is fixed at an angle of Alternatively, when the user sets the operation of the louver 7 to auto swing with the remote control, the louver 7 is in the range of the minimum angle to the maximum angle, and performs the auto swing operation.

Moreover, when the operation of the indoor unit 1 is started, indoor air is sucked from the suction unit 12 of the centrifugal fan 9 through the suction port 4 and the suction grille 6, and the centrifugal fan 9 ) Is discharged in the outer circumferential direction from the discharge portion 13 of. After the air discharged from the centrifugal fan 9 is cooled or heated through the heat exchanger 10, the air conditioning air is formed on the outer circumferential surface of the heat exchanger 10 and the inner circumferential surface of the housing 2. It blows out into the room from the blowout port 5 formed in the said makeup panel 3 via the air path 14 which becomes.

At this time, if the louver 7 is set to the angle of downward blowout, the said air-conditioning air is blown out downward, and if it is set to the angle of horizontal blowout, it will be taken out in substantially horizontal direction (horizontal direction). In addition, when set to the above-mentioned auto swing, the louver 7 ranges from the minimum angle to the maximum angle, and performs the auto swing operation, so that the air-conditioning air is moved from a direction close to horizontal in accordance with the movement of the louver 7. It is taken out to a direction close to the vertical.

In Fig. 2, 15 is a bell mouse which is disposed below the centrifugal fan 9 and has an opening raised toward the suction part 12 of the centrifugal fan 9 while gradually decreasing the diameter to the center part. This bell mouse 15 is for guiding the air sucked from the suction port 4 to the centrifugal fan 9. In addition, the bell mouse 15 partitions the inner space of the housing 2 into the suction side and the discharge side of the centrifugal fan 9 together with the drain pan 11.

16 is an electrical appliance box that houses a control board or the like for controlling the operation of the indoor unit 1, and the electrical appliance box 16 is provided on the lower surface of the bell mouse 15. 17 is a suction filter installed above the suction grille 6.

Next, the structure of the louver 7 vicinity in which the louver 7 is in a fully closed state, ie, the state where the louver 7 is in a fully closed angle (0 degree), is demonstrated using FIG. FIG. 3 is a cross-sectional view of one main part of the blowout ports shown in FIGS. 1 and 2, and the louver is in a fully closed angle state. FIG. When the operation of the indoor unit 1 is stopped, the louver 7 is in a state of a fully closed angle shown in FIG. 3, and prevents foreign matter from entering the indoor unit while the indoor unit 1 is stopped. The design at the time of stopping is improved.

As shown in FIG. 3, the fully closed angle (0 degree) of the louver 7 generally does not completely block the ejection opening 5, but the left end part and the right end part of the louver 7, A slight gap is formed between the wall surfaces of the makeup panel 3 which forms the blowout outlet 5, and it is comprised so that the wall surface of the louver 7 and the blowout outlet 5 may not interfere.

In addition, in FIG. 3, 3a is a heat insulating material, such as foamed styrol which forms the said blowout opening 5. As shown in FIG.

As shown in Fig. 1, the louver 7 is formed in an elongate plate-like or wing shape extending from one end in the longitudinal direction of the outlet 5 to the other end, and the louver 7 is the length thereof. It is fixed to the central axis 18 extending in the direction through the mounting member 19. The said central shaft 18 is rotatably supported by the support member (not shown) arrange | positioned at the both end side, The rotation is controlled by a stepping motor etc.

FIG. 4 is a cross-sectional view of one main part of the blowout ports shown in FIGS. 1 and 2 and illustrates a minimum angle and a maximum angle of the louver during indoor unit operation. That is, FIG. 4 shows the operating range of the louver 7 in the state where the indoor unit 1 is in operation, and the louver 7a indicated by the solid line is a louver that can be set by the user with a remote controller (not shown). The louver 7b which shows the minimum angle (1st angle) of 7) and shows it by the dashed-dotted line has shown the maximum angle (2nd angle) of the louver 7 which can be set by a user with a remote control.

When the louver 7 is set at the position 7a of the minimum angle (first angle), the air-conditioning air blown out from the blowout port 5 is a horizontal blowout operation taken out in a substantially horizontal direction. On the other hand, when the louver 7 is set at the position 7b of the maximum angle (second angle), the air-conditioning air blown out from the blowout port 5 is a downward blowout operation taken out in a substantially vertical direction.

In addition, when the said fully closed angle which is the angle of the louver at the time of stopping the indoor unit 1 shown in FIG. 3 is 0 degree, in this embodiment, let the said minimum angle (1st angle) be 28 degrees, for example, The maximum angle (second angle) is, for example, 64 degrees. In addition, what is necessary is just to set the said minimum angle (1st angle) arbitrarily in the range of about 27-30 degree, for example. In addition, what is necessary is just to set the said maximum angle (2nd angle) arbitrarily, for example in the range of about 60-70 degree | times.

The angle of the louver 7 during operation of the indoor unit 1 can be set not only by the remote controller to the above-mentioned minimum and maximum angles, but also by the remote controller in a plurality of steps between the above-described minimum and maximum angles by several degrees. It is possible. For example, it is comprised so that the angle of a 5th stage (2nd stage-6th stage) can be set between the 1st stage and the 7th stage, making the minimum angle the 1st stage, the maximum angle the 7th stage. Incidentally, the angle of the louver 7 is not limited to seven steps, and may be larger or smaller than that. Moreover, you may comprise so that a louver angle can be set to arbitrary angles steplessly.

When the operation of the louver 7 is set to auto swing by the remote controller, the louver 7 is sequentially rotated from the first stage, the first angle, which is the angle at the start of the auto swing setting, e. The furnace angle increases to the seventh stage, which is the maximum angle, and thereafter, the sixth stage, the fifth stage,. The reciprocating operation is repeated, such as decreasing to the first angle, the minimum angle.

The auto swing is not limited to the reciprocating operation between the first stage and the seventh stage, and may be configured to perform the reciprocating operation of the third stage to the seventh stage, for example. In addition, during the auto swing, the louver angle may be configured to smoothly change steplessly.

In the indoor unit of the air conditioner as described above, for example, in a heating operation, in a high load operation where the temperature difference between the outside air temperature and the room temperature is very large, it is performed to blow out the wind direction so that the warm air is supplied downward. Although blown out, it may not be possible to reach the bottom surface sufficiently.

Moreover, as another means for reducing the opening area of the blowout port 5 of the indoor unit 1, the louver of the blowout port of some of the said blowout ports 5 provided in 4 is completely closed as shown in FIG. By setting it as a position (position at the time of stop of operation), it is also conceivable to increase the wind speed at the remaining blowout port.

However, when the indoor unit is operated with the louver 7 of some blowout ports 5 in the fully closed position, the louver in the fully closed position is greatly warped by the wind pressure of the blown air, and the blown air is at a high temperature. The resin louver has a problem that it is easy to cause plastic deformation when it is operated for a long time.

The structure of the indoor unit of the air conditioner of this embodiment which solves the said subject is demonstrated using FIG. 5 and FIG. FIG. 5: is sectional drawing of the principal part of the blowout port shown in FIG. 1, FIG. 2, The figure explaining the 3rd angle of the louver in this Embodiment 1, FIG. 6 is the 3rd angle of the louver shown in FIG. It is a figure explaining the action in a phosphorus state.

In FIG. 5, the position 7a of the louver 7 shown by a dashed-dotted line shows the case where the said louver 7 is set to the position of the minimum angle (1st angle), and the louver represented by a dashed-dotted line similarly ( The position 7b of 7) has shown the case where the said louver 7 is set to the position of the largest angle (2nd angle). The positions 7a and 7b of these louvers 7 are angles of the louver 7 which can be set by a remote control (not shown), and are a function normally provided with the conventional indoor unit. In addition, the louver 7 is also generally equipped with a function of auto swinging in the range of the first angle position 7a to the second angle position, and can be set by a remote controller.

In this embodiment, as shown in Fig. 5, the angles of the louvers 7 at the four ejection ports 5 shown in Fig. 1 are angles of the louvers at the time of stopping the indoor unit shown in Fig. 3. It is comprised so that it may be set to the position 7c of the 3rd angle larger than a fully closed angle (0 degree louver angle) and smaller than the 1st angle which is the minimum opening degree of the said louver 7 which can be set with a remote control.

The position 7c of the third angle of the louver 7 is not an angle that can be set by the user with the remote control, but is an indoor unit of the air conditioner in the case of predetermined predetermined driving conditions, such as at the start of heating operation. 1) Angle position of the louver 7 set automatically from the control apparatus (not shown) provided in etc.

For example, when the first angle is 28 degrees, the third angle is greater than 0 degrees, which is a fully closed angle when the indoor unit is stopped, and is larger than the first angle (28 degrees), which is the minimum angle that can be set by the remote controller. Small angles, for example 14 degrees. The third angle is not limited to 14 degrees, but may be arbitrarily set in a range of 5 to 25 degrees, preferably in a range of 10 to 18 degrees.

That is, in the present embodiment, when the minimum angle (first angle) which is the angle of the louver 7 which can be set by the remote controller is set as the first stage, and the maximum angle (second angle) is set as the seventh stage, It is corresponded to the angle of 0.5 step | paragraph, and this angle of 0.5 step | paragraph is an angle set automatically in the case of predetermined | prescribed driving conditions from the control apparatus provided in the indoor unit 1 etc., not the louver angle which a user can set with a remote control. to be.

In the present embodiment, as described above, each louver 7 is configured to be set at the position 7c of the third angle (0.5 step angle), and when the air conditioner is a predetermined operating condition determined in advance. Of the louvers 7 of the plurality of ejection openings 5, the louver 7 of some ejection openings 5 is set at the position 7c of the third angle.

The louver 7 of the part blowout outlet 5 is set at the position of the said 3rd angle (an angle larger than the fully closed angle of the louver and smaller than a 1st angle), and as shown by the circle of hatching in FIG. 6, the blowout opening ( A small gap 21 can be formed between the wall surface of 5) and the end of the louver 7. Therefore, since airflow can be taken out from this clearance 21, the curvature of the louver by wind pressure can be reduced. Therefore, since the curvature of the louver 7 can be suppressed small, even if hot air is blown out indoor, it can suppress that a louver plastically deforms.

In addition, the louver 7 set to the third angle may be configured to be sequentially switched every predetermined time. In addition, the louver 7 of the other outlet 5 is provided with a louver operation which can be set by the remote controller. That is, the other louvers 7 are set to auto swing, or set to an arbitrary louver angle.

Predetermined predetermined operation conditions of an air conditioner are following operating conditions, for example, and when the following operation | movement is performed, the louver of the blowout outlet of some louvers of a plurality of blower openings will be, for example, an indoor unit ( What is necessary is just to be comprised so that it may set to the said 3rd angle automatically from the control apparatus (not shown) provided in 1).

(1) When heating operation is set.

(2) In the case of heating operation or cooling operation, when the temperature difference between the outside air temperature and the room temperature is operated under a high load operation condition that is larger than a predetermined predetermined temperature difference.

(3) In the case of the high speed blowout setting in which the blown air reaches farther than usual, such as near the bottom, during heating operation or cooling operation.

(4) When a stirring operation for increasing the blowout wind speed during heating operation or the like and for reducing the temperature difference between the upper and lower parts of the room is set, or when the control device of the air conditioner automatically executes the stirring operation.

In addition, as mentioned above, when the user cannot set arbitrary louvers to the said 3rd angle with a remote control as mentioned above, when the high speed blowout setting etc. are made, it is from the control apparatus of an air conditioner. The angle that is set automatically. For example, when any of the operations (1) (3) (4) described above is set, or when it is operated under the condition of (2) or when the stirring operation of (4) is automatically performed, Automatically from the control device, the angle of the louver 7 of the blowout port 5 is set to the third angle position.

Since the opening area of the blowout port 5 of the louver part set at the said 3rd angle becomes small by this structure, the air volume blown out from the blowout port 5 is reduced significantly, and the blowout wind velocity from the other blowout port 5 is reduced. It can increase enough. Accordingly, it is possible to reach the blown out air to a sufficiently far position such as the bottom surface.

Moreover, in the blowout port 5 of the louver part set at the said 3rd angle, the above-mentioned small clearance 21 can be formed between the wall surface of the blowout port 5 and the edge part of the said louver 7, and this clearance ( Since the airflow can be taken out from 21), the warpage of the louver 7 due to wind pressure can be reduced. Therefore, even when the large amount of hot air is blown out by increasing the rotational speed of the centrifugal fan 9, since the warpage of the louver 7 can be reduced, the plastic deformation of the louver 7 can be suppressed. have.

In addition, in the above description, when the predetermined predetermined driving condition is reached, the angle of the louver of some of the ejection outlets is set to the third angle among the plurality of ejection outlets. You may also

That is, when the predetermined operating condition is set, the louver 7 does not directly control the angle of the louver 7 of the ejection port of some of the plurality of ejection openings 5 to the third angle, but first the louver 7 performs plastic deformation. The louver 7 may be controlled at the third angle after the predetermined time has elapsed after a predetermined time for a predetermined time that does not occur.

With this configuration, when the louver 7 is maintained at the fully closed angle, the blowout wind speed from the other blowout port 5 can be made larger than when the louver 7 is controlled at the third angle. Can be further improved. Moreover, since the louver 7 is controlled at the third angle before the louver 7 controlled at the fully closed angle causes plastic deformation, the effect that plastic deformation of the louver 7 can also be prevented is obtained.

In the above description, the minimum angle that can be set by the remote controller is set as the first angle, and the louver angle larger than the fully closed angle which is the angle of the louver at the time of the indoor unit stop and smaller than the first angle is set as the third angle. Instead, you may comprise as follows.

That is, when it has a function to auto swing a louver, let the minimum angle of the louver at the time of auto swing be a 1st angle, and set the louver angle larger than the fully closed angle which is the angle of the louver at the time of indoor unit stop, and smaller than the said 1st angle. You may set to a 3rd angle.

As described above, in the present embodiment, the indoor unit stops the angle of the louver 7 of the part of the plurality of outlets 5 among the plurality of outlets 5 under predetermined predetermined operating conditions, such as when a high speed blowout setting or the like is made. It is set to a third angle larger than the fully closed angle (0 degree), which is the angle of the louver of the city, and smaller than the first angle, which is settable by the remote control or smaller than the minimum angle of auto swing, and the louver 7 of the other outlet is Since it is set to 2 angles or auto swing, the curvature of the louver 7 provided in each ejection opening 5 can also be suppressed, enabling high speed ejection from the some ejection opening of the some ejection opening 5.

Next, the louver operation | movement in the conventional indoor unit 1 and the louver operation | movement in the indoor unit 1 in this Embodiment 1 are demonstrated using FIGS. FIG. 7 is a view for explaining the louver operation at the start operation in the indoor unit of the conventional air conditioner and at the subsequent stirring operation; FIG. 8 is a start operation at the start operation and subsequent stirring operation in FIG. A diagram illustrating the short circuit phenomenon when all the louvers are pulled out downward, and FIG. 9 illustrates the louver operation during start-up operation in the indoor unit of the air conditioner of the first embodiment and during the stirring operation thereafter. FIG. 10: is a figure explaining the louver operation | movement, the flow of blown air, and the flow of intake air at the time of the stirring operation shown in FIG.

In the conventional indoor unit, at the start-up operation of the heating operation, as shown in FIG. 7, the louvers 7A to 7D of the four blowout ports 5 shown in FIG. 1 have the above-described second angle (downward ejection). (I.e., the maximum angle), then all of the louvers 7A to 7D perform auto swing operation after a predetermined time has elapsed, and stirring operation is performed. In addition, stirring operation is performed for a predetermined time, and after that, normal operation is performed.

For this reason, at the time of heating start operation, the wind direction of all four blowout openings 5 becomes a 2nd angle (downward blowout) simultaneously. In addition, since all the louvers 7A to 7D perform an auto swing operation during the stirring operation performed after a predetermined time elapses, all four louvers 7A to 7D simultaneously perform the second angle ( Downward extraction) in some cases.

In this way, when all four louvers 7A to 7D are blown out downward, as shown in FIG. 8, before the heated warm blow-out air 22 is spread in the indoor space R, the center of the indoor unit 1 is discharged. The phenomenon which is sucked into the inlet 4 provided in the lower surface, ie, the short circuit phenomenon (refer to the flow 23 of the short circuit), tends to occur. For this reason, while the heating capability of an air conditioner falls and the hot high temperature blow-out air is directly inhaled, there exists a subject that the efficiency of an air conditioner also falls.

In addition, in FIG. 8, 24 has shown the flow of the indoor cold air sucked into the suction port 4 of the said indoor unit 1 from the vicinity of the floor surface F which forms the indoor space R. As shown in FIG.

The indoor unit of the air conditioner of this Embodiment 1 which solved the said subject of the indoor unit of the conventional air conditioner is demonstrated using FIG. 9 and FIG. In the first embodiment, in order to improve the short circuit phenomenon described above, the louvers 7A to 7D of the four blowout ports 5 shown in FIG. 1 are controlled as shown in FIG. 9. Also in the present Example 1, at the time of a heating start operation, the wind direction of the louvers 7A-7D of all four ejection openings 5 is simultaneously controlled by the said 2nd angle (downward ejection), and is shown in FIG. Are controlled together.

In the point where the indoor unit 1 of this Embodiment 1 differs from the conventional one shown in FIG. 7, FIG. 8, it is control of the louvers 7A-7D in the stirring operation performed after a predetermined time elapses. . In this embodiment, when the stirring operation is performed, among the louvers 7 of the four blowout ports 5, the louvers 7B to 7D of the three blowout outlets 5 perform an auto swing operation to carry out the stirring operation. As shown in FIG. 9, the louver 7A of a part of the louvers 7 of the blowout outlet 5 is controlled at the third angle (out of the horizontal or more blowout) described using FIG. 5. will be.

The third angle (out-of-horizontal taking out) is a minimum opening degree of the louver 7 that is larger than the fully closed angle (the louver angle of 0 degrees), which is the angle of the louver at the time of stopping the indoor unit shown in FIG. It is an angle smaller than 1 angle (1st step angle) (0.5 step angle), for example, an angle of 14 degrees etc., for example.

In addition, as described above, the position 7c of the third angle of the louver 7 is not an angle that can be set by the user with the remote control, and the indoor unit of the air conditioner when the predetermined predetermined operating condition is achieved ( 1) It is an angular position of the louver 7 set automatically from the control apparatus with which it is equipped.

In the conventional one, since all the louvers 7A to 7D perform the auto swing operation during the stirring operation, all four louvers 7A to 7D may be downward during this auto swing operation. As described with reference to FIG. 8, there has been a problem of generating a short circuit phenomenon. In contrast, in the first embodiment, the louver 7A of one blowout port 5 is set to the third angle (out of the horizontal or higher drawout), and the following effects are obtained.

That is, as shown in FIG. 10, from the blowout port 5 provided with the said louver 7A which becomes the 3rd angle, as shown by blowout air 22a, it is located above the indoor space R (ceiling (20) side) is taken out. For this reason, since the passageway 25 for intake air is formed below the blowout port 5 provided with the louver 7A, the cool air below in the indoor space R is the flow 24 of the indoor air. As shown, it is easily sucked from the suction port 4 of the indoor unit 1. As a result, it is possible to suppress a short circuit phenomenon (see FIG. 8) in which a part of the hot blowing air is directly sucked from the inlet 4, thereby suppressing the suction of the heated hot blowing air directly from the inlet, Since the cool air below in the indoor space R can be sucked into the indoor unit 1 efficiently, the effect that the efficiency of an air conditioner can also be improved is acquired.

In addition, since the louver 7A is set at the position of the third angle, as shown by the hatching circle in FIG. 6, a small gap 21 is formed between the wall surface of the outlet 5 and the end of the louver 7. Can be formed. Therefore, since the airflow can be blown out from the gap 21, the warpage of the louver 7A due to the wind pressure can be reduced, so that the louver is plastically deformed even when the hot air is blown out into the room. Is also obtained.

As described above, according to the first embodiment, there is an effect that an indoor unit of an air conditioner capable of suppressing short circuits and also preventing warpage of louvers can be obtained. Further, high speed ejection is possible from the ejection opening 5 having louvers other than the louvers set at the third angle.

In addition, the operation | movement of the heating start operation shown in FIG. 9 is performed when a user sets high load heating mode etc., and when a high load heating mode etc. is set, the air conditioner automatically heats starting operation shown in FIG. Perform the operation of. Immediately after the start of the heating operation, the starting operation is carried out for a predetermined time, for example, about 30 minutes, and then shifts to the stirring operation. This stirring operation is performed for about 10 minutes, and after that, it transfers to normal operation which a user can set freely with a remote control.

Example 2

Embodiment 2 of the indoor unit of the air conditioner of this invention is demonstrated using FIG. Since the basic structure of the indoor unit 1 is the same as that of the said Example 1 demonstrated using FIGS. 1-6, FIG. 10, the description of the same part is abbreviate | omitted and this Example 2 is a part different from the said Example 1 Explain the center.

It is a figure explaining the louver operation | movement at the time of the starting operation in the Example 2 of the indoor unit of an air conditioner, and the stirring operation after that. Also in the present Example 2, at the time of a heating start operation, the direction of the wind of the louvers 7A-7D of all four ejection openings 5 is simultaneously controlled by the said 2nd angle (downward ejection), and is shown in FIG. The same is controlled.

The difference between the indoor unit 1 of the second embodiment and the first embodiment described above is that as shown in FIG. 11, the louvers 7A to 7D in the stirring operation performed after a predetermined time elapses from the heating start operation. Is in control. In the second embodiment, when the stirring operation is performed, among the louvers 7 of the four outlets 5, the louvers 7B to 7D of the three outlets 5 perform the auto swing operation, but the stirring operation is actually performed. The louver 7A of the ejection opening 5 of some of the louvers 7 of the four ejection openings 5 is controlled at the third angle (horizontal or higher ejection) as shown in FIG. 9.

However, in this Embodiment 2, it is predetermined time for the louver 7A to be controlled by the said 3rd angle, and after that, among the louvers 7 of the four ejection openings 5, of three ejection openings 5 The louvers 7A, 7C, and 7D perform an auto swing operation so that stirring operation is performed, and the louver 7B of the ejection opening 5 of some of the louvers 7 of the four ejection openings 5 is moved to the third angle ( Take out more than horizontal) is fixed and controlled.

In addition, when a certain time elapses, this time, the louvers 7A, 7B, and 7D of the three ejection openings 5 perform auto swing operation, and stirring operation is performed, and the said 3rd angle (horizontal) with respect to louver 7C is performed. After a certain time elapses, the louvers 7A to 7C of the three outlets 5 perform an auto swing operation, and stirring operation is performed, and the louver 7D is described above. It is controlled to be fixed at a 3rd angle (ejection more than horizontal). Thereafter, the same operation is repeated every predetermined time so that the stirring operation is performed. In addition, after completion | finish of stirring operation, it shifts to normal operation.

As shown in this FIG. 11, the following effects are acquired by controlling the louver which becomes a 3rd angle at the time of stirring operation so that it may switch sequentially every fixed time progress.

That is, the interior space below the louver at the third angle (out of the horizontal or more taken out) becomes difficult to warm up, but the configuration of the second embodiment provides an effect that the bias of the room temperature can be alleviated.

Example 3

Embodiment 3 of the indoor unit of the air conditioner of this invention is demonstrated using FIG. It is a figure explaining the louver operation | movement at the time of the starting operation in the Example 3 of the indoor unit of the air conditioner, and the stirring operation after that. In addition, since the basic structure of the indoor unit 1 is the same as that of the said Example 1 demonstrated using FIGS. 1-6, FIG. 10, the description of the same part is abbreviate | omitted and this Example 3 is the same as that of the said Example 1 The explanation focuses on the different parts.

In the present Example 3, the wind direction of the louvers 7A and 7C of some (two in this example) among the louvers 7 of the four blowout ports 5 at the time of a heating start operation simultaneously has the said 2nd angle. It is controlled by (downward ejection), and the other louvers 7B and 7D are controlled to be controlled by the third angle (outwardly or more horizontally).

In addition, in the third embodiment, the control of the louvers 7A to 7D in the stirring operation performed after the heating start operation has elapsed for a predetermined time is controlled in the same manner as in the first embodiment described in FIG. 9. That is, in the third embodiment, when the stirring operation is performed, among the louvers 7 of the four outlets 5, the louvers 7B to 7D of the three outlets 5 perform the auto swing operation to perform the stirring operation. The louver 7A of the blowout outlet 5 of some of the louvers 7 of the four blowout outlets 5 is comprised so that it may be controlled by the said 3rd angle (out of a horizontal or more ejection), as shown in FIG. .

According to the third embodiment, since some louvers 7B and 7D are controlled at the third angle in the down ejection operation during the heating start operation, the louvers are taken out downward from the other louvers 7A and 7C. It is possible to obtain a high-speed take-off that further increases the wind speed, so that the ambient temperature of a person in the indoor space can be raised early. In addition, since the louvers 7B and 7D are controlled at the third angle, a passage 25 for suction air 25 (see FIG. 10) is provided below the blowout port 5 including the louvers 7B and 7D. Since the cold air in the indoor space R is sucked in easily from the suction port 4 of the indoor unit 1, the short circuit phenomenon described in FIG. 8 can also be suppressed.

In addition, the control of the louvers 7A to 7D in the stirring operation performed after the heating start operation has elapsed for a predetermined time is performed in the same manner as in the first embodiment shown in FIG. You can warm it all up.

In addition, in this Embodiment 3, since some louvers are controlled at the said 3rd angle also in any of heating start operation | movement and stirring operation, as demonstrated using FIG. 6, the deflection of the louver by wind pressure can be reduced. Even if the hot air is blown out into the room, the louver can be suppressed from plastic deformation.

In addition, in the above description of the third embodiment, an example in which the louvers 7B and 7D are controlled at the third angle during the heating start operation has been described, but the louvers controlled at the third angle may be 7A, 7C, or 4 Only one of the louvers may be controlled at the third angle. In addition, although the example which controlled 7 A of louvers at the 3rd angle at the time of stirring operation was demonstrated, the louver to control at 3rd angle should just control any one louver among 4 louvers at said 3rd angle, Alternatively, any of a plurality of louvers may be configured to control the third angle.

As described above, according to each embodiment of the present invention, an air conditioner having a plurality of air outlets provided to surround the inlet port and a plurality of louvers provided at the respective air outlets and configured to adjust the ejection direction thereof. In the indoor unit of the present invention, at the time of heating operation, the angle of the louver of the part of the plurality of outlets is set to a third angle smaller than the first angle which is larger than the fully closed angle and the minimum angle that can be set by the remote controller, The louver at the other ejection opening is configured to be set to downward ejection or auto swing. Therefore, even when the louvers other than the louver set at the third angle become the second angle which is the maximum angle set by the remote controller, the indoor air (cold air) is sucked under the louver controlled at the third angle. Since the passage can be secured, the short circuit can be suppressed.

That is, since the air is blown out at an angle equal to or greater than the horizontal direction from the blowout port provided with the louver controlled at the third angle, a passage passage is formed below the louver in which cold air under the indoor space is sucked into the intake port of the indoor unit. Therefore, occurrence of a short circuit can be suppressed.

In addition, since the louvers of some of the plurality of outlets are set at the third angle, the wind speeds taken out from the other outlets can be increased, and the surrounding temperature of the person in the indoor space can be raised early, Stirring operation can be performed efficiently. Moreover, since the effect of the wind pressure of hot air can be alleviated on the louver set at the said 3rd angle, the effect that a louver bends and plastic deformation can also be suppressed is obtained.

In addition, this invention is not limited to the Example mentioned above, A various modified example is included. For example, in Examples 1 to 3 described above, an example in which all the louvers are set to the second angle (downward blowout) or some of the louvers to the third angle (outside horizontal or more) during the heating start operation has been described. The louver may be set to auto swing, or a part of the louvers may be set to the third angle, and another louver may be autoswing.

In addition, the above-mentioned embodiment was described in detail in order to demonstrate this invention easily, and it is not necessarily limited to having all the structures demonstrated.

1: indoor unit
2: housing
3: cremation panel
3a: insulation
4: inlet
5: outlet
6: suction grill
7: louver
7a: position of minimum angle (first angle)
7b: position of maximum angle (second angle)
8: motor
9: centrifugal fan
10: heat exchanger
11: drain pan
12: suction part
13: discharge part
14: cooker
15: Bell Mouse
16: electrical appliance box
17: suction filter
18: central axis
19: mounting member
20: ceiling
21: gap
22, 22a: blown air
23: Short Circuit Flow
24: indoor air flow
25: With passage of intake air
F: bottom
R: interior space

Claims (10)

In the indoor unit of an air conditioner, comprising: a suction port, a plurality of blowout ports provided to surround a periphery of the inlet port, and a plurality of louvers provided at each of the blowout ports and configured to control the blowout direction,
When the indoor unit is stopped, the louver is rotated in the direction of closing the outlet, and the angle of the louver at the time of stopping the indoor unit rotated in the direction of closing the outlet is set to a fully closed angle.
When the indoor unit is provided with a remote control for setting the operation of the louver, when the minimum angle of the angle of the louver that can be set by the remote control is set to the first angle, the maximum angle to the second angle,
At the time of heating operation, the angle of the louver of the some blowout outlet among a plurality of said blowout outlets is set to the 3rd angle larger than the fully closed angle which is an angle of the louver at the time of indoor unit stop, and smaller than the said 1st angle, and another said blowout outlet The louver of the indoor unit of the air conditioner, characterized in that set to auto swing. The method of claim 1,
The indoor unit is an indoor unit of an air conditioner, wherein the indoor unit is a four-way indoor unit provided with four outlets provided with louvers around the suction port. The method of claim 1,
The louver set to the third angle is controlled to the third angle after the louver is maintained at a completely closed angle for a predetermined time. The method of claim 1,
When the fully closed angle, which is the angle of the louver at the time of stopping the indoor unit, is 0 degrees, the first angle is in the range of 27 to 30 degrees, and the second angle is in the range of 60 to 70 degrees, each arbitrarily set, and the third An indoor unit of an air conditioner, wherein an angle is arbitrarily set within a range of 5 to 25 degrees. The method of claim 4, wherein
An indoor unit of an air conditioner, wherein the third angle is arbitrarily set in a range of 10 to 18 degrees. The method of claim 1,
At the start of the heating operation, the louvers of all the outlets are set to downward ejection, and after a predetermined time elapses, the louver angle of some of the outlets is set to the third angle, and the louvers of the other outlets are set to the third angle. An indoor unit of an air conditioner, characterized by being set to auto swing. The method of claim 1,
An indoor unit of an air conditioner, wherein the louver set at the third angle is configured to be sequentially switched every predetermined time. In the indoor unit of an air conditioner, comprising: a suction port, a plurality of blowout ports provided to surround a periphery of the inlet port, and a plurality of louvers provided at each of the blowout ports and configured to control the blowout direction,
When the indoor unit is stopped, the louver is rotated in the direction of closing the outlet, and the louver angle at the time of stopping the indoor unit rotated in the direction of closing the outlet is set as a completely closed angle.
When the indoor unit is provided with a remote control for setting the operation of the louver, when the minimum angle of the louver angle settable by the remote control to the first angle, the maximum angle to the second angle,
At the time of heating operation, the angle of the louver of some of the blowout ports is set to a third angle larger than the fully closed angle which is the louver angle at the time of the indoor unit stop and smaller than the first angle, The louver is an indoor unit of an air conditioner, characterized by being set to downward blowout. The method of claim 8,
The indoor unit is a four-way indoor unit provided with four outlets provided with louvers around the suction port,
In the start-up operation immediately after the start of heating operation, the louvers of some of the four outlets are controlled at the third angle, while the louvers of the other outlets are set to downward ejection, and after a predetermined time elapses, The louver of the blower outlet is set at the said 3rd angle, and it performs auto stirring of the louver of several other blower outlet, and performs stirring operation, The indoor unit of the air conditioner characterized by the above-mentioned. The method of claim 8,
The louver set to the third angle is controlled to the third angle after the louver is maintained at a completely closed angle for a predetermined time.

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