JP2008101868A - Indoor unit of air conditioner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To stably control an airflow angle and air distributing performance and to prevent dew condensation on a blade. <P>SOLUTION: In this indoor unit 1 of the air conditioner, the blade 21 is rotatably disposed on a supply opening 6. The blade 21 has a main blade 23, and a sub-blade 25 disposed separately from the main blade 23 and rotated integrally with the main blade 23. A wall portion 31 of the supply opening 6 has a recessed portion 32 at a negative pressure face 23A side of the main blade 23 to increase the airflow at the negative pressure face 23A side. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an indoor unit of an air conditioner.

An air conditioner cools or heats a room by circulating a refrigerant between a heat exchanger of an outdoor unit and a heat exchanger of an indoor unit. The indoor unit includes a suction port for sucking indoor air, a heat There is an air outlet for blowing the exchanged air into the room. Here, in an indoor unit of the type where the air outlet is formed almost directly below, a blade that controls the direction of air flow of temperature-controlled air is attached, so that the cool air does not blow out directly during cooling operation, and heating operation Sometimes the blowing direction is changed so that warm air reaches near the floor.
Here, as a conventional indoor unit, there is one disclosed in Patent Document 1. This indoor unit is provided with a deflection guide that makes the cross-sectional area of the flow path into which the temperature-controlled air that has passed through the heat exchanger flows constant, and the wind speed at the enlarged flow path section where the flow path expands rapidly downstream of the deflection guide. Is made uniform and then guided to the blade in the outlet. The blower outlet has a shape that is greatly curved, and a blade is rotatably supported. By greatly curving the air outlet, the distance from the blade is maintained even when the blade is directed obliquely downward during the cooling operation. As a result, the distance between the upper surface of the blade and the outlet end portion of the blow-off channel facing the blade is reduced, and the resistance of the blow-out port is prevented from increasing.
JP-A-8-94160

When the indoor unit is thinned, it becomes difficult to secure a sufficient flow path length for blowing out the temperature-controlled air, so the flow path length is ensured by combining the flow path in the indoor unit and the outlet. There was a need. However, if the air outlet is greatly curved as in a conventional indoor unit, the flow path between the upstream end of the blade and the curved wall surface of the air outlet becomes large when the blade is directed almost directly below. The air blowing performance was easy to deteriorate.
In addition to this, since the width of the flow path formed by the upstream end of the blade and the wall surface of the air outlet greatly varies depending on the angle of the blade, it is difficult to control the airflow angle and the wind speed.
Further, the greatly curved flow path at the air outlet tends to involve hot and humid room air on the back side of the blade during the cooling operation. Temperature-controlled air flows on the surface of the blade, and the entire blade is cooled below the dew point temperature, so that moisture in the entrained room air was likely to condense on the blade.
The present invention has been made in view of such circumstances, and it is a main object of the present invention to enable stable control of the airflow angle and the air blowing performance and to prevent blade condensation.

The invention according to claim 1 of the present invention that solves the above problems is an indoor unit of an air conditioner that sucks indoor air from a suction port and blows out air that has been temperature-controlled by a heat exchanger from a blower outlet, A first blade that is rotatably provided at the air outlet and deflects the direction of the air blown from the air outlet, and is spaced apart from the first blade to form a part of the blowout flow path And a second blade that rotates integrally with the first blade, and the wall of the outlet facing the first blade has a distance from the first blade It was set as the indoor unit of the air conditioning apparatus characterized by having provided the recessed part which increases this.
In the indoor unit of the air conditioner, the blowing direction is controlled by the temperature-controlled air mainly passing between the first and second blades. Since the wall portion of the air outlet on the suction surface side of the first blade is recessed, when the first and second blades are arranged upward during cooling operation, the space between the first blade and the wall portion is The amount of air that blows through increases.

  According to the present invention, since the first and second blades are integrally rotatable at the outlet, the blowing direction is controlled, and an appropriate blowing angle is realized in each of the cooling operation and the heating operation. it can. Since the concave portion is provided in the wall portion of the air outlet facing the first blade, the flow rate flowing between the first blade and the wall portion during the cooling operation can be increased, and condensation of the first blade is prevented.

The best mode for carrying out the invention will be described in detail with reference to the drawings.
As shown in FIG. 1, the indoor unit 1 has a box-shaped unit body 2 embedded in a ceiling 4 through a decorative panel 3. The decorative panel 3 is fixed to the ceiling surface 4 using an outer edge portion, and the suction port 5 and the air outlet 6 are formed to be separated toward the room. A filter 7 is attached to the inside of the unit body 2 inside the suction port 5. Further, a drain pan 8 is fixed to the inner surface of the decorative panel 5 between the suction port 5 and the air outlet 6.

  The unit body 2 has an opening formed downwardly closed with a decorative panel, and a flow path from the suction port 5 to the outlet 6 is formed by a space in the unit body 2. In this flow path, the heat exchanger 10 and the ventilation fan 11 are arrange | positioned in order from the suction inlet 5 side. The heat exchanger 10 has a structure in which a refrigerant flows inside, and a lower end portion 10 </ b> A is in contact with the inside of the drain pan 8. The heat exchanger 10 extends obliquely from the lower end portion 10 </ b> A to above the suction port 5, and the upper end portion 10 </ b> B is in contact with the ceiling surface of the unit body 2. The blower fan 11 bulges a part of the ceiling surface of the unit main body 2 downward to form a throttle portion 13, while the stabilizer 14 fixed to the decorative panel 3 and the scroll 16 on the unit main body 2 side. And the flow axis is arranged at a narrowed position, and the rotating shaft 11A extends in a direction substantially orthogonal to the flow path. The flow path from the blower fan 11 to the blower outlet 6 is a blowout flow path 15 provided in order to suppress rectification and generation of vortices. The stabilizer 14 extends continuously along the axial direction of the blower fan 11, and is between the shape of the stabilizer 14 and the curved scroll 16 formed in the indoor unit 2 so as to face the stabilizer 14. The distance and the like are designed so that the air volume and speed of the air flowing through the blowing flow path 15 are substantially uniform.

As shown in FIG. 2, a blade 21 is rotatably attached to the air outlet 6 by a pin 22. The blade 21 is disposed on the side of the stabilizer 14 and has a main blade (first blade) 23 for airflow angle control and a sub-blade (second blade) attached to both ends of the main blade 23 in the longitudinal direction via connecting members 24. Blade) 25.
The main blade 23 extends from the upstream side to the downstream side in the blowing direction of the temperature-controlled air, and the downstream end protrudes from the air outlet 6 to the indoor side. The downstream end is slightly inclined with respect to the upstream end in a sectional view. The main blade 23 may have a smoothly curved shape or a linear shape.
The sub blade 25 is disposed away from the main blade 23. The cross-sectional shape of the sub-blade 25 is provided with one bent portion 26 that protrudes toward the main blade 23 along the longitudinal direction on the upstream side. The upstream end of the bent portion 26 extends in a direction away from the main blade 23, and the downstream end of the bent portion 23 extends substantially parallel to the main blade 23.

  The shape of the blowout port 6 of the decorative panel 3, that is, the shape of the blowout channel is determined according to the blade 21. The air outlet 6 has a substantially straight shape downward, and the wall 31 on the main blade 23 side of the flow path formed by the air outlet 6 is formed using the side wall of the drain pan 8. The wall portion 31 is formed with a concave portion 32 that curves so as to expand the flow path from the vicinity of the position corresponding to the upstream end when the main blade 23 is most upward. In addition, the height of the upper end of the recessed part 32 exists in the position lower than the bending part 26 of the subblade 25 arrange | positioned upward. The end portion 31 </ b> A of the wall portion 31 is slightly projected toward the main blade 23.

The wall surface on the sub-blade 25 side of the flow path formed by the air outlet 6 has different shapes for the upstream wall portion 35 connected to the unit body 2 and the downstream wall portion 36 on the outlet end side.
The upstream wall portion 35 is a portion facing the upstream end portion of the sub blade 25 when the main blade 23 is arranged most upward, and is centered on the rotation center of the blade 21, that is, the pin 22 in a sectional view. The curved surface has an arc shape. The radius of the arc is set to be slightly larger than the locus when the upstream end portion or the downstream end portion of the sub blade 25 is rotated around the pin 22.
The downstream wall portion 36 is formed continuously from the upstream wall portion 35, and is formed from an inclined surface that is inclined in the direction in which the opening width of the outlet 6 is increased. In addition, you may make it into the curved surface which has a circular arc different from the upstream wall part 35 instead of making the downstream wall part 36 into an inclined surface.

FIG. 2 shows an arrangement when the blade 21 is rotated most upward. At this time, the bent portion 26 of the sub blade 25 is disposed higher than the upstream end portion of the main blade 23, and the upstream end portion of the sub blade 25 substantially coincides with the wall surface 16 </ b> A of the blowing flow path 15 of the unit body 2. To do. At this time, the downstream end of the sub-blade 25 continues to the wall 31 of the air outlet 6 of the decorative panel 3. As a result, the sub-blade 25 becomes a part of the blowout flow path 15 and forms an inclined flow path wall surface on the outlet side.
On the other hand, as shown in FIG. 3, when the main blade 21 is rotated most downward, the upstream end portion of the sub blade 25 is lowered from the upstream end portion of the main blade 23. An end portion of the sub blade 25 on the downstream side of the bent portion 26 is disposed on a substantially extended line of the wall surface 16 </ b> A of the blowing channel 15 of the unit body 2. As a result, the sub-blade 25 becomes a part of the blowing channel 15 and forms a substantially straight channel wall surface downward along the blowing channel 15.

  As shown in FIG. 3, the difference θθ (= θ1−θ2) between the angle θ1 at which the main blade 23 is most downward with respect to the horizontal line and the angle θ2 at which the main blade 23 is most upward as shown in FIG. The angles θs formed by the two straight lines connecting the respective upper and lower ends and the center of rotation substantially coincide with each other. Thereby, the flow (secondary flow) of the airflow flowing in the vicinity of the upstream wall portion 35 can be minimized. Further, since the gap between the sub blade 25 and the wall portions 35 and 36 is reduced, the blowing sound can be suppressed to a low level.

The operation of this embodiment will be described.
When heating the air conditioner including the indoor unit 1, the gas refrigerant pressurized by the compressor of the outdoor unit is caused to flow into the heat exchanger 10 of the indoor unit 1. At the same time, the blower fan 11 is operated to suck indoor air from the suction port 5. The air sucked into the flow path of the indoor unit 1 passes through the filter 7, passes through the heat exchanger 10, and exchanges heat with the refrigerant in the heat exchanger 10. Air is heated by the heat released when the refrigerant condenses. The temperature-controlled air flows from the blower fan 11 into the blowout flow path 15 and is rectified so that the wind speed distribution and the air volume become substantially uniform, and then passes through the air outlet 6 of the decorative panel 3 and enters the room. Blown out.

  At this time, the indoor unit 1 lowers the blade 21 as shown in FIG. The downstream end portions of the main blade 23 and the sub blade 25 are arranged substantially in parallel with the flow of temperature-controlled air. As a result, a downward airflow is formed and the room is heated. Part of the temperature-controlled air flows between the main blade 23 and the wall 31, that is, toward the negative pressure surface 23 </ b> A side of the main blade 23.

  When performing the cooling operation, the gas refrigerant pressurized by the compressor of the outdoor unit is liquefied by the heat exchanger of the outdoor unit, and then flows into the heat exchanger 10 of the indoor unit 1. The air sucked into the flow path of the indoor unit 1 from the room by the blower fan 11 passes through the filter 7, passes through the heat exchanger 10, and exchanges heat with the refrigerant in the heat exchanger 10. The air is cooled by the heat it takes when the refrigerant evaporates. The air thus temperature-controlled flows from the blower fan 11 into the blowout flow path 15 and is rectified so that the wind speed distribution and the air volume become substantially uniform, and then passes through the air outlet 6 of the decorative panel 2 into the room. Blown out.

  At this time, the indoor unit 1 raises the blade 21 as shown in FIG. The main blade 23 and the sub blade 25 deflect the blowing direction of the temperature-controlled air and blow off obliquely. Since the upstream end portion of the sub blade 25 is disposed close to the upper end of the upstream wall portion 35 having a curved wall surface, the temperature-controlled air is blown into the room with little passage between the sub blade 25 and the upstream wall portion 35. . On the other hand, on the main blade 23 side, the amount of temperature-controlled air flowing between the main blade 23 and the wall portion 31, that is, on the negative pressure surface 23 </ b> A side of the main blade 23 is increased by having the recess 32 in the wall portion 31. . As a result, although the blowing direction is deflected by the blade 21, the blowing flow rate is ensured. Further, since hot and humid air in the room is not caught on the negative pressure surface 23A side of the main blade 23, condensation of the main blade 23 is prevented.

According to this embodiment, the blade 21 is provided with the sub blade 25 that rotates integrally with the main blade 23 so that the sub blade 25 deflects the flow path on the outlet side of the blowing flow path 16 according to the operating state. Therefore, a stable air flow angle can be obtained in each of the cooling operation and the heating operation, and the air blowing performance can be stabilized. For this reason, the temperature of the room can be comfortably adjusted.
Since the recess 32 is provided in the flow path in the air outlet 6, the airflow flowing to the negative pressure surface 23A side of the main blade 23 during the cooling operation can be increased, and condensation of the main blade 23 can be prevented.

  Here, FIG. 4 to FIG. 7 show the results of experiments on blowing sound and air volume using the indoor unit 1. 4 and 5 show the blade angle during heating operation, that is, the measurement result in the most downward direction, and FIG. 4 shows the relationship between the air volume and the blowing sound. FIG. 5 shows the relationship between the fan speed and the air volume. FIG. 6 and FIG. 7 are measurement results of the blade angle during the cooling operation, that is, the measurement result in the most upward direction, and show the relationship between the air volume and the blowing sound and the relationship between the fan rotation speed and the air volume, respectively. 4 to 7, for comparison, the measurement results of the conventional indoor unit having only one blade are displayed in an overlapping manner.

  At the time of heating operation, as shown in FIG. 4, the blowing sound of the indoor unit 1 was smaller than the blowing sound of the conventional indoor unit within the measured air volume range. That is, the indoor unit 1 quietly blows out the temperature-controlled air, and comfort is improved. As shown in FIG. 5, the air volume of the indoor unit 1 was larger than the air volume of the conventional indoor unit within the range of the measured fan speed. That is, although the indoor unit 1 has the two blades 21, the operation efficiency is better than that of the conventional indoor unit.

  Moreover, the result of having measured about the distribution of the blowing speed of the temperature control air at the time of air_conditionaing | cooling operation | movement, and an airflow direction is shown in FIG. The blowing speed was measured for each of the distances L1 and L2 downward from the air outlet 6 and measured at a plurality of locations in the horizontal direction with the outlet end of the air outlet 6 as a zero point. In FIG. 6, in order to facilitate understanding, it is shown upside down. The distance L1 was about 50 mm, and the distance L2 was about 100 mm. At the distance L1, the peak position of the speed hardly changes between the indoor unit 1 and the conventional indoor unit. However, in the region where the horizontal distance is short, that is, in the horizontal direction and close to the outlet end, the indoor unit 1 has a slightly larger wind speed distribution. This is because the airflow blown out between the wall portion 31 and the blade 21 is increased by providing the recess 32 in the air outlet 6. In the wind speed distribution at the distance L2, the indoor unit 1 has a peak in a region farther in the horizontal direction than the conventional indoor unit. This is because the temperature-controlled air is blown obliquely by the blade 21 as compared with the conventional case. That is, as shown by the solid line arrow in the figure, the air flow direction of the indoor unit 1 was able to blow off more obliquely in the horizontal direction than the air flow direction of the conventional indoor unit (the direction of the arrow indicated by the broken line). . During cooling operation, cold temperature-controlled air does not directly hit the indoor person, so comfort is improved.

A modification of this embodiment will be described with reference to FIGS.
As shown in FIG. 7, a dew condensation prevention layer 51 is provided on the outer surface of the sub blade 25. For the dew condensation prevention layer 51, for example, flocking or a heat insulating material is used. By providing such a dew condensation preventing layer 51, dew condensation on the sub blade 25 can be prevented.
As shown in FIG. 8, a plurality of third blades 52 that are rotatably supported by the main blade 23 and the sub blade 25 may be intermittently arranged in the longitudinal direction of the blade 21. Since the third blade 52 can be rotated so as to intersect the air flow blowing direction by rotating around the rotation shaft 53, the blowing angle of the air flow is also controlled in the longitudinal direction of the blade 21. It becomes possible. The dew condensation preventing layer 51 of the sub blade 25 may or may not be provided.
As shown in FIG. 9, the air outlet 6 on the main blade 23 side may be a substantially straight wall portion 55. The wall surface 55 is formed by extending the stabilizer 14 and extends downward. In this case, the position of the wall portion 55 is set so that a sufficient amount of airflow can be passed between the wall surface 55 and the negative pressure surface 23A of the main blade 23 to prevent condensation.

Note that the present invention can be widely applied without being limited to the above-described embodiment.
For example, the configuration and arrangement of the indoor unit 1 are not limited to those illustrated. Moreover, the indoor unit 1 is not limited to the type installed in a ceiling surface.

It is sectional drawing which shows schematic structure of the indoor unit which concerns on embodiment of this invention. It is sectional drawing which expands and shows a blower outlet, Comprising: It is the figure which raised the braid | blade most. It is sectional drawing which expands and shows a blower outlet, Comprising: It is the figure which lowered | hung the blade most. It is a graph which shows the result of having investigated the relationship between the air volume at the time of heating operation, and a ventilation sound. It is a graph which shows the result of having investigated the relationship between the fan rotation speed at the time of heating operation, and an air volume. It is a graph which shows the result of having measured the wind speed at the time of air_conditionaing | cooling operation, changing each of the vertical distance from a blower outlet, and a horizontal position. It is the figure which provided the dew condensation prevention layer in the subblade. It is a figure which shows the braid | blade which has a 3rd braid | blade. The wall surface on the main blade side is a substantially straight view.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Indoor unit 5 Intake port 6 Outlet 10 Heat exchanger 15 Outlet flow path 21 Main blade (1st blade)
23 Sub blade (second blade)
26 Bent part 31 Wall part 32 Concave part 51 Condensation prevention layer

Claims (3)

It is an indoor unit of an air conditioner that sucks indoor air from a suction port and blows out air temperature-controlled by a heat exchanger from a blower outlet,
A first blade that is rotatably provided at the air outlet and deflects the direction of the air blown from the air outlet, and is spaced apart from the first blade to form a part of the blowout flow path And a second blade that rotates integrally with the first blade, and the wall of the outlet facing the first blade has a distance from the first blade An indoor unit of an air conditioner, characterized in that a recess for increasing the pressure is provided.   The second blade has an upstream end bent in a direction away from the first blade, and the wall of the outlet has a locus when the upstream end is rotated. The indoor unit of the air conditioner according to claim 1, wherein the indoor unit is recessed in a substantially arc shape.   The indoor unit of the air conditioner according to claim 1 or 2, wherein the second blade is provided with a flocked surface facing the first blade or provided with a heat insulating layer.

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