JP4498313B2 - Air conditioner - Google Patents

Description

  The present invention relates to an air conditioner that harmonizes indoor air.

  Patent Documents 1 and 2 disclose conventional air conditioners that take in indoor air to harmonize and send out conditioned air from a blowout port. The air conditioner disclosed in Patent Document 1 is provided with infrared sensors in a plurality of indoor areas, and the temperature of each area is detected by the infrared sensor. And the direction of the blowing airflow is changed based on the detected temperature to eliminate the temperature difference between the regions. Moreover, the air conditioner disclosed by patent document 2 can make indoor temperature uniform by sending conditioned air upward from a blower outlet.

  On the other hand, Patent Literature 3 discloses an air conditioner that intensively air-conditions two locations apart from each other in a room. In this air conditioner, for example, conditioned air is sent to the left from the upper part of the outlet, and conditioned air is sent to the right from the lower part. Moreover, it has the 1st, 2nd heat exchanger arrange | positioned in series, and the 1st, 2nd path | route which connects a 1st, 2nd heat exchanger is branched and provided. An opening / closing valve is provided in the first path, and an expansion valve and a capillary tube are provided in the second path.

When the on-off valve is opened and the expansion valve is closed, the first and second heat exchangers have the same cooling capacity. When the on-off valve is closed and the expansion valve is opened, the refrigerant flowing through the refrigeration cycle flows into the second heat exchanger via the capillary tube, so that the cooling capacity of the second heat exchanger is higher than that of the first heat exchanger. . Thereby, the temperature sent from the upper part of the blower outlet through which a large amount of air passing through the first heat exchanger circulates is slightly higher in temperature than the air sent from the lower part of the blower outlet. For this reason, the space of the upper left part of an air conditioner can be made into high temperature, and the space of the lower right part can be made into low temperature.
Japanese Patent Publication No.7-88957 JP 2003-232560 A JP 2003-240325 A

  According to the air conditioner disclosed in Patent Documents 1 and 2, the temperature in the room is substantially uniform. For this reason, when there are a plurality of users in the room, there is a problem that the comfort cannot be satisfied for each user if the temperature at which each user feels comfortable is different. Moreover, even if the indoor temperature distribution is in a non-uniform state as described in the conventional example of Patent Document 2, it cannot be matched with the temperature at which each user feels comfortable.

  On the other hand, according to the air conditioner disclosed in Patent Document 3, the temperature difference between the first and second heat exchangers is formed depending on whether or not the refrigerant flowing through the refrigeration cycle passes through the capillary tube. For this reason, the temperature difference between the two spaces that are intensively air-conditioned is substantially constant. As a result, when the blowout temperature is controlled so that the user in one space feels comfortable, the temperature in the other space is determined in conjunction. Therefore, there may be a case where the temperature is not comfortable for the user in the other space, and there is a problem that the comfort cannot be satisfied for each user.

  An object of the present invention is to provide an air conditioner that can satisfy comfort for a plurality of users in a room.

In order to achieve the above object, the present invention provides an air conditioner that sends conditioned air from an air outlet provided in an indoor unit to a room, and one of a left air outlet on the left side of the air outlet and a right air outlet on the right side. First up and down wind direction varying means for varying the wind direction of the second, second up and down wind direction varying means for varying the other wind direction up and down, and one of the left air outlet and the right air outlet is varied left and right. 1 left and right wind direction varying means, and second left and right wind direction varying means for varying the other wind direction to the left and right,
During the cooling operation, the first left / right air direction variable means and the first up / down air direction variable means blow air obliquely upward from one of the left outlet and the right outlet, and the second left / right air direction variable means and the second up / down air direction variable. A first operation mode in which air is blown obliquely upward from the other of the left air outlet and the right air outlet to make the room a uniform temperature, and first left and right air direction variable means and first vertical air direction variable means during cooling operation It is distributed along the side wall of the indoor unit side by blowing a first air stream in a substantially horizontal direction or downward inclined outwardly in the lateral direction with respect to the front from one of the left outlet and the right air outlet by together, the second horizontal wind changing means and the second vertical airflow direction changing means by the left outlet and the ceiling wall of the room wherein an other from different directions to the left and right and up and down with the first air stream on the right outlet It is circulated along the top wall blown a second stream cow, first by dividing one room vertical plane dividing the indoor unit to the right and left, and a second operation mode of providing a temperature difference in the second region It is characterized by having.

  Further, in the air conditioner having the above-described configuration, the present invention blows air downward from one of the left outlet and the right outlet by the first left and right air direction changing means and the first up and down air direction changing means during the cooling operation, A third operation mode is provided in which air is blown downward from the other of the left air outlet and the right air outlet by the second left and right air direction varying means and the second vertical air direction varying means.

  According to the present invention, in the air conditioner having the above-described configuration, a blower path that communicates from a suction port for sucking indoor air to the blower outlet is formed inside the indoor unit, and the blower path is directed downward as it goes forward. And the front wall of the air flow path has an inclined surface that slopes upward as it goes forward from the end of the front guide. .

  According to the present invention, in the air conditioner configured as described above, the first and second up-and-down wind direction varying means are made of the same member having flexibility.

  According to the present invention, the temperature of the first and second regions obtained by dividing one room into left, right, front, back, top, bottom, etc. is independently controlled, so that even when the temperature at which a plurality of users feel comfortable is different, Comfort can be satisfied.

  Further, according to the present invention, the air sent from the indoor unit is circulated along at least one of the ceiling wall and the side wall of the room, so that air conditioning can be performed without directly receiving cold air in the living area in the lower center of the room. . Accordingly, it is possible to prevent the user's health from being impaired.

  Further, according to the present invention, the first air flow blown out from the air outlet in one of the left and right directions or in the horizontal direction is circulated along the one side wall, and the second air flow blown upward in the front is directed to the ceiling wall in the room. Since it distribute | circulates along, a temperature difference can be easily provided in the 1st, 2nd area | region which divided the room | chamber interior into right and left. In addition, the user's health is not impaired because the living area in the lower center of the room is not directly exposed to cold air.

Moreover, according to the present invention, first, when providing a temperature difference in the second region, the lever is circulated along the air flow blown out from the air outlet to the upper front to the interior of the top wall, first divided into front and rear, the A temperature difference can be easily provided in two regions. In addition, the user's health is not impaired because the living area in the lower center of the room is not directly exposed to cold air.

Moreover, according to the present invention, lever is circulated along the side wall of the air flow blown into the underneath direction or downward rearward indoor unit is installed through the outlet, the first divided vertically, a simple temperature difference in the second region Can be provided. In addition, the user's health is not impaired because the living area in the lower center of the room is not directly exposed to cold air.

<< First Embodiment >>
Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a perspective view showing an indoor unit 1 of an air conditioner according to the first embodiment. The indoor unit 1 of the air conditioner has a main body held by a cabinet 2, and a front panel 3 provided with suction ports 4 on the upper surface side and the front surface side is detachably attached to the cabinet 2. The cabinet 2 is provided with a claw portion (not shown) on the rear side surface, and is supported by engaging the claw portion with a mounting plate (not shown) attached to the indoor side wall W1 (see FIG. 2).

  A blower outlet 5 for sending out air is provided at the front lower portion of the front panel 3. The blower outlet 5 is formed in the rectangle extended in the horizontal direction. The air outlet 5 is closed by four lateral louvers 111a, 111b, 111c, and 111d. The lateral louver 111a is arranged at a position that closes the upper part of the left outlet 5a that forms the left half toward the outlet 5. The horizontal louver 111b is arranged at a position that closes the upper part of the right outlet 5b that forms the right half of the outlet 5. The horizontal louver 111c is arranged at a position to close the lower part of the left outlet 5a. The horizontal louver 111d is arranged at a position to close the lower portion of the right outlet 5b.

  The horizontal louvers 111a, 111b, 111c, and 111d have horizontal rotation shafts and rotate independently by driving a drive motor (not shown). Accordingly, the horizontal louvers 111a and 111c change the vertical direction of the airflow sent from the left outlet 5a. The horizontal louvers 111b and 111d change the vertical direction of the airflow sent from the right outlet 5b.

  FIG. 2 is a side sectional view of the indoor unit 1. Inside the indoor unit 1, a blower path 6 that communicates from the suction port 4 to the blowout port 5 is formed. A blower fan 7 that sends out air is disposed in the blower path 6. For example, a cross flow fan or the like can be used as the blower fan 7. The blower path 6 is inclined downward as it goes forward, and has a front guide portion 6a that guides the air sent out by the blower fan 7 forward and downward. Moreover, the upper wall of the ventilation path 6 is an inclined surface that is inclined upward as it goes forward from the end of the front guide portion 6a.

  The front guide portion 6a is provided with a plurality of vertical louvers 12a (see FIG. 3) and 12b. FIG. 3 shows a top view of the vertical louvers 12a and 12b. The plurality of vertical louvers 12a arranged on the left side are each supported at the center by a support shaft 12d substantially perpendicular to the front guide portion 6a, and the rear portions are connected by a connecting member 12c. As a result, the plurality of vertical louvers 12a rotate in conjunction with each other and vary the airflow direction in the left-right direction of the airflow sent from the left outlet 5a.

  Similarly, the plurality of vertical louvers 12b arranged on the right side are each pivotally supported at the center by a support shaft 12f substantially perpendicular to the front guide portion 6a, and the rear portions are connected by a connecting member 12e. As a result, the plurality of vertical louvers 12b rotate in conjunction with each other and vary the airflow direction in the left-right direction of the airflow sent from the right outlet 5b.

  In FIG. 2, an air filter 8 that collects and removes dust contained in the air sucked from the suction port 4 is provided at a position facing the front panel 3. An indoor heat exchanger 9 is disposed between the blower fan 7 and the air filter 8 in the blower path 6. The indoor heat exchanger 9 is connected to a compressor (not shown) provided in an outdoor unit arranged outdoors, and the refrigeration cycle is operated by driving the compressor.

  The indoor heat exchanger 9 is cooled to a temperature lower than the ambient temperature during the cooling operation by the operation of the refrigeration cycle. Further, during the heating operation, the indoor heat exchanger 9 is heated to a temperature higher than the ambient temperature. A temperature sensor 61 is provided between the indoor heat exchanger 9 and the air filter 8 to detect the temperature of air sucked from the suction port 4, and the air conditioner is driven on the side of the indoor unit 1. A control unit (not shown) for controlling is provided. A drain pan 10 that collects condensation that has fallen from the indoor heat exchanger 9 during cooling or dehumidification is provided in the lower part before and after the indoor heat exchanger 9.

  FIG. 4 is an external view showing a remote controller 31 for controlling the operation of the air conditioner of the present embodiment. The remote controller 31 has an operation unit 31a, a display unit 31b, and a transmission unit 31c. The operation unit 31a has a plurality of operation keys, and inputs an operation state of the air conditioner.

  The operation key of the operation unit 31a can be switched to an indoor cooling operation, a dehumidifying operation, or a heating operation. When the lower cover 31d is opened, another operation key is exposed, and the set temperature, wind direction, and wind speed can be set. In addition, the first and second regions obtained by dividing the room into left and right, front and rear, and top and bottom can be set separately.

  The display unit 31b includes a liquid crystal display panel or the like, and displays the operating condition, time, set temperature, and the like of the air conditioner. Further, the schematic shape of the room R in which the indoor unit 1 is installed and the schematic installation position of the indoor unit 1 are schematically displayed in a perspective view. For example, the set temperatures of the first and second regions divided into the left and right, front and rear, or top and bottom toward the indoor unit 1 can be set separately. In addition, the transmission unit 31 c transmits an operation signal from the operation unit 31 a to the indoor unit 1.

  Further, the user can set the wind speed to “light wind”, “weak wind”, “strong wind”, “automatic”, or the like. Thereby, it can be manually changed to a light breeze (about 4 m / s for a 6 tatami type air conditioner), a weak breeze (about 6 m / s), a strong breeze (about 8 m / s). In addition, when “automatic” is set, it can be switched to a light breeze, a light breeze, a strong breeze, etc. according to the driving situation.

  In the air conditioner having the above configuration, when a compressor (not shown) is driven, refrigerant from the outdoor unit (not shown) flows to the indoor heat exchanger 9 to operate the refrigeration cycle. Indoor air is sucked into the indoor unit 1 from the suction port 4 by driving the blower fan 7, and dust contained in the air is removed by the air filter 8.

  During the cooling operation, the air taken into the indoor unit 1 is cooled by exchanging heat with the indoor heat exchanger 9 on the low temperature side. The conditioned air cooled by the indoor heat exchanger 9 is sent out into the room with its direction regulated in the left-right direction and the up-down direction by the vertical louvers 12a, 12b and the horizontal louvers 111a, 111b, 111c, 111d.

<First air flow control>
In order to make the temperature distribution in the room uniform, the first airflow control is performed. As shown in FIG. 5, the upper horizontal louvers 111a and 111b are arranged at an angle of, for example, 20 ° with respect to the horizontal so that the front is upward. The lower lateral louvers 111c and 111d are arranged at an angle of 5 ° or less with respect to the horizontal, for example, between the diagonally lower side where the front is slightly lower and substantially horizontal. Further, the vertical louvers 12a and 12b are arranged facing the front as shown in FIG. The vertical louvers 12a and 12b may be inclined in a range up to about 5 ° with the front facing outward. Then, the wind speed is set to “light wind”, and conditioned air is sent out from the outlet 5.

  The air that flows through the blowing path 6 and is delivered from the upper part of the outlet 5 is guided obliquely upward along the horizontal louvers 111a and 111b. The air that flows through the blowing path 6 and is sent out from the lower part of the outlet 5 is guided slightly downward or substantially horizontally along the horizontal louvers 111c and 111d. At this time, the air that swirls clockwise in the drawing by the blower fan 7 in the drawing and circulates increases the air volume at the upper part of the blower path 6 on the inner peripheral side. For this reason, the air sent out from the lower part of the blower outlet 5 follows the air sent out from the upper part. As a result, the conditioned air is sent obliquely upward as indicated by an arrow B from the air outlet 5.

  Although the lower lateral louvers 111c and 111d may be arranged so as to be higher as they go forward, the air may be guided upward, but the conditioned air flowing along the lower surfaces of the lateral louvers 111c and 111d decreases. For this reason, a temperature difference may arise between the upper surface and the lower surface of the horizontal louvers 111c and 111d, which may cause condensation. Therefore, it is more desirable to arrange the horizontal louvers 111c and 111d between obliquely below and substantially horizontal.

  The air sent diagonally upward from the blower outlet 5 circulates along the ceiling wall S due to the Coanda effect, and reaches the side wall W2 (see FIG. 16) facing the indoor unit 1 while diffusing. And it falls along the side wall W2, distribute | circulates the floor surface F (refer FIG. 16), and conditioned air distribute | circulates the whole in the room R. As shown in FIG. As a result, the room is cooled to a uniform temperature.

  As will be described in detail later, when the wind speed of the air sent from the outlet 5 is increased, the conditioned air is guided to a long distance while maintaining a low temperature during the cooling operation. For this reason, the temperature farther from the indoor unit 1 is lower than that closer.

<Second air flow control>
Next, the second airflow control is performed when the regions obtained by dividing the room into left and right by the operation unit 31a are set to different temperatures. The display unit 31b of the remote controller 31 shown in FIG. 4 described above sets the set temperature of the first area E1 on the left side (see FIG. 10) toward the indoor unit 1 to 24 ° C., and the second area E2 on the right side (FIG. 10) is set to 26 ° C. The first and second regions E1 and E2 are divided by a vertical plane that divides the indoor unit 1 into left and right.

  When the cooling operation is started at the set temperature, the vertical louvers 12a and 12b are arranged as shown in FIG. That is, the right vertical louver 12b is arranged in a direction toward the front. The left vertical louver 12a is arranged, for example, inclined at 40 ° to the left as it goes forward. For example, the right vertical louver 12b may be inclined slightly to the right by 5 °, for example, in the range where the inclination angle is smaller than that of the vertical louver 12a.

  The right lateral louvers 111b and 111d are arranged in the same manner as in FIG. That is, the upper lateral louver 111b is arranged at an angle of 20 ° with respect to the horizontal, for example, so that the front is upward. The lower lateral louver 111d is disposed at an angle of 5 ° or less with respect to the horizontal, for example, between the diagonally lower side where the front is slightly lower and substantially horizontal. The left lateral louvers 111a and 111c are arranged as shown in FIG. That is, the horizontal louvers 111a and 111c are arranged between an obliquely lower side and a substantially horizontal side, which is slightly lower as it moves forward. For example, the horizontal louver 111a is arranged horizontally, and the horizontal louver 111c is arranged so that the front is 10 ° below the horizontal. FIG. 8 is a perspective view of the indoor unit 1 showing this state.

  Then, similarly to the first airflow control, the wind speed is set to “slight wind”, the blower fan 7 is driven, and conditioned air is sent out from the blowout port 5 as shown in FIG. That is, the conditioned air is sent from the left outlet 5a toward the left substantially horizontal or slightly leftward as indicated by the arrow A. In addition, it is sent while being inclined leftward by an inclination angle α with respect to a vertical plane that divides the indoor unit 1. As shown by the arrow B, conditioned air is sent from the right outlet 5b obliquely upward in the front.

  FIG. 10 shows a flow state of the air sent into the room. Air (B) airflow (hereinafter referred to as “second airflow”) delivered from the right outlet 5b circulates along the ceiling wall S due to the Coanda effect while diffusing left and right, and gradually decreases the speed. And it falls along the wide range of the side wall W2 facing the indoor unit 1.

  The airflow (A) sent from the left outlet 5a (hereinafter referred to as “first airflow”) flows along the left side wall W3 toward the indoor unit 1 and reaches the side wall W2. Then, the second airflow merges with the first airflow and circulates on the floor surface F.

  The inclination angle α (see FIG. 9) of the first airflow is preferably 20 ° or more. When the indoor unit 1 is provided in the center of the shorter side wall W1 with the room R in FIG. 10 between 6 tatami mats, the direction from the center of the indoor unit 1 to the corner where the side walls W2, W3 intersect is a vertical plane perpendicular to the side wall W1. Inclined about 20 °. Therefore, when the inclination angle α of the first airflow is set to 20 ° or more, the first airflow can be reliably made to follow the side wall W3. When the room R is between 8 tatami mats or when the indoor unit 1 is in front and horizontally long, the inclination angle α can be set to be larger than 20 ° along the side wall W3.

  Since the second air flow (B) is sent out toward the front, the first region E1 on the left side of the room R and the second region E2 on the right side of the room R are cooled with the same cooling capacity by the second air flow (B). On the other hand, since the first air flow (A) is sent leftward, the first air flow (A) cools the first region E1 on the left side of the room R more than the second region E2. As a result, the average temperature of the first region E1 is lower than the average temperature of the second region E2.

  For example, when ½ each of conditioned air is sent out from the left outlet 5a and the right outlet 5b, the first and second regions are each ¼ of the conditioned air sent out from the outlet 5 by the second air flow. It is cooled with each cooling capacity. In addition, the first region is cooled by the first airflow with a cooling capacity of about ½ of the conditioned air sent from the blowout port 5. Thereby, the cooling capacity of 3/4 of the conditioned air sent from the blower outlet 5 is supplied to the first region.

  Further, as shown in FIG. 6 described above, the vertical louver 12a is inclined, so that the first air flow (A) sent from the left outlet 5a has an air volume due to an increase in pressure loss and a decrease in cross-sectional area due to the vertical louver 12a. Decrease. For this reason, the temperature of the first air stream (A) becomes lower than the second air stream by heat exchange with the indoor heat exchanger 9. Therefore, the average temperature of the first region E1 can be further lowered than the average temperature of the second region E2.

  FIGS. 11-14 has shown the temperature distribution in the room R at the time of 2nd airflow control. The size of the room R is 6 tatami mats (height 2400 mm, width 3600 mm, depth 2700 mm). 11 to 14 show the measurement results of the cross sections of the alternate long and short dash lines D1 and D2 and two-dot chain lines D3 and D4 in FIG.

  The D1 cross section is a position parallel to the side wall W3 and 675 mm from the side wall W3, and is a cross section at a position on the left side of the indoor unit 1 in the room R. The cross section D2 is a position parallel to the side wall W4 facing the side wall W3 and 675 mm from the side wall W4, and is a cross section at a position on the right side ¼ toward the indoor unit 1 in the room R. The cross section D3 is a position parallel to the side wall W1 and 1200 mm from the side wall W1, and is a cross section at a position 1/3 ahead of the indoor unit 1 in the room R. The D4 cross section is a cross section at a position parallel to the side wall W2 facing the side wall W1 and 1200 mm from the side wall W2, and at a position 1/3 rearward toward the indoor unit 1 in the room R.

  According to these figures, the temperature of the first region E1 on the left side of the room R toward the indoor unit 1 is controlled to about 24 ° C. In addition, the temperature of the second region E2 on the right side of the indoor unit 1 is controlled to about 26 ° C. Therefore, the temperature difference between the first and second regions E1 and E2 can be set at about 2 ° C.

  At this time, air flows from the side wall W2 toward the side wall W1 in the living space in the lower central portion of the room R. For this reason, the air sent out from the blower outlet 5 is decelerated, the wind speed of 1st area | region E1 is 0.1 m / s or less, and the wind speed of 2nd area | region E2 is about 0.2 m / s. Therefore, cold air does not directly pour into the living space, and an extremely low-speed airflow flows, so that it is possible to prevent the health of the user from being impaired. If the wind speed is 0.5 m / s or less, the user feels almost no wind. For this reason, the rotation speed of the ventilation fan 7 is determined so that the wind speed of living space may be 0.5 m / s or less.

The first air stream (A) has an air volume of 2.5 m ³ / min, a wind speed of 3 m / s, and a blowing temperature of 10 ° C. The second air stream (B) has an air volume of 5 m ³ / min, and the wind speed is 6 m / s. s, the blowing temperature is 15 ° C. As described above, the air volume and the wind speed are different due to pressure loss and the like, and the blowing temperature of the first air stream (A) is low. Moreover, since the wind speed of 1st airflow is low, the quantity of the conditioned air which circulates from the 1st area | region E1 to the 2nd area | region E2 reduces, and the quantity stagnated in the 1st area | region E1 increases. Thereby, the temperature of the first region E1 can be made lower than that of the second region E2 more easily.

  The heat exchanger 9 may be divided into left and right parts so that the respective heat exchangers have different temperatures, and a temperature difference between the first and second airflows may be provided. Further, the blower fan 7 may be divided into left and right, and the respective blower fans may have different rotation speeds, and the first and second airflows may have different wind speeds and air volumes. Thus, the temperature of the first and second regions can be adjusted more finely.

  Moreover, since conditioned air is sent in different directions from the left and right left outlets 5a and 5b of the outlet 5, comfort can be improved. That is, when conditioned air is sent in different directions from above and below the air outlet 5, a temperature difference is generated between the upper and lower surfaces of the horizontal louver. As a result, condensation may occur on the horizontal louver, and water may be sprayed on the user or the user may be uncomfortable by flooding the room. On the other hand, if conditioned air is sent out from the left outlet 5a and the right outlet 5b in different directions, occurrence of a temperature difference between the upper and lower surfaces of the lateral louvers 111a to 111d is suppressed, and condensation is prevented and comfort is improved.

<Third airflow control>
When the temperature difference between the first and second regions E1 and E2 is set larger by operating the remote controller 31, the third airflow control is performed. In the third airflow control, the vertical louver 12a and the horizontal louvers 111a to 111d are arranged in the same manner as in the second airflow control. The right vertical louver 12b is disposed such that the front is inclined toward the inner side (left side).

  Since the vertical louver 12b is arranged with the front inclined toward the inside (left side), the second air flow (B) sent out from the right outlet 5b is located on the left side of the second region E2 on the right side of the room R. More messages are sent to the first area E1. For this reason, more cooling capacity is provided in the first region E1 on the left side than the second region E2 on the right side of the room R. However, since the total amount of air sent out from the blower outlet 5 decreases, the rotational speed of the blower fan 7 is increased and the air volume is increased. Further, the absolute room temperature of the first and second regions E1 and E2 is adjusted by changing the rotational speed of the compressor (not shown).

  For example, when the set temperatures of the first and second regions E1 and E2 are 23 ° C. and 26 ° C., respectively, the right vertical louver 12b is 10 ° toward the inside (left side) with respect to the first airflow control. Inclined. Further, the rotational speed of the blower fan 7 is set to 110%, and the rotational speed of the compressor (not shown) is set to 105%.

  When the set temperatures of the first and second regions E1 and E2 are 22 ° C. and 26 ° C., respectively, the right vertical louver 12b is inclined 20 ° toward the inside (left side) with respect to the first airflow control. Arranged. Further, the rotational speed of the blower fan 7 is set to 120%, and the rotational speed of the compressor (not shown) is set to 110%.

  As described above, the vertical louver 12b is disposed so that the inclination angle α is inclined toward the inner side (left side), and the air volume sent to the first area E1 of the second airflow (B) is increased to increase the first area E1. The cooling capacity increases, and the temperature of the first region E1 becomes lower than that of the second airflow control. Thereby, the temperature difference of 1st, 2nd area | region E1, E2 can be enlarged. Therefore, the first and second regions E1 and E2 are independently brought to a desired temperature by increasing or decreasing the ratio of the amount of air sent to the first region E1 and the second region E2 depending on the wind direction of the second airflow (B). The temperature can be controlled.

  Moreover, you may increase / decrease the ratio of a 1st airflow by further subdividing the vertical louvers 12a and 12b and the horizontal louvers 111a-111d divided into right and left. Blower fans may be provided on the left and right sides to individually vary the air volumes of the first and second airflows.

  In the second and third airflow control, the case where the first region E1 is set to a temperature lower than that of the second region E2 has been described. However, the vertical louvers 12a and 12b and the horizontal louvers 111a to 111d are symmetrical to each other. By disposing the second region E2, the temperature of the second region E2 can be made lower than that of the first region E1.

<Fourth air flow control>
Next, the fourth airflow control is performed when the regions obtained by dividing the room into the front and rear by the operation unit 31a are set to different temperatures. FIG. 15 shows that the set temperature of the first area E3 (see FIG. 16) near the indoor unit 1 is set to 26 ° C. by operating the remote controller 31, and the set temperature of the second area E4 (see FIG. 16) on the far side. Is set to 24 ° C. The first and second regions E3 and E4 are divided by a vertical plane that divides the central portion of the room R.

  When the cooling operation is started at this set temperature, the vertical louvers 12a and 12b are arranged toward the front as in FIG. The vertical louvers 12a and 12b may be inclined in a range up to about 5 ° with the front facing outward. Further, the horizontal louvers 111a, 111b, 111c, and 111d are arranged in the same manner as in FIG. That is, the upper lateral louvers 111a and 111b are arranged at an angle of 20 ° with respect to the horizontal, for example, so that the front is upward. The lower lateral louvers 111c and 111d are disposed at an angle of, for example, 5 ° or less with respect to the horizontal between the diagonally lower side where the front is slightly lower and substantially horizontal.

  And the rotation speed of the ventilation fan 7 is set to 140% with respect to the time of 1st airflow control, and conditioned air is sent out diagonally upward from the blower outlet 5. FIG. At this time, the blowing wind speed is equivalent to “weak wind” (in the case of a 6 tatami type air conditioner, for example, 6 m / s). As shown in FIG. 16, the air sent diagonally upward from the blower outlet 5 circulates along the ceiling wall S due to the Coanda effect, and reaches the side wall W2 facing the indoor unit 1 while diffusing. Then, it descends along the side wall W <b> 2 and flows through the floor surface F.

  At this time, since the blown wind speed is high, the conditioned air does not rise in temperature while circulating along the ceiling wall S, and reaches far while maintaining a low temperature. For this reason, the average temperature of the 1st field E3 near the outdoor unit 1 becomes higher than the average temperature of the 2nd field E4 on the far side.

  FIG. 17 shows the temperature distribution in the room R during the fourth airflow control. The size of the room R is 6 tatami mats (height 2400 mm, width 3600 mm, depth 2700 mm) as described above. FIG. 17 shows the measurement result of the central section of the room R indicated by the alternate long and short dash line D shown in FIG.

  According to the figure, the temperature of the first region E3 of the room R near the indoor unit 1 is controlled to about 26 ° C. Further, the temperature of the second region E4 far from the indoor unit 1 is controlled to about 24 ° C. Therefore, the temperature difference between the first and second regions E3 and E4 can be set to about 2 ° C.

  At this time, air flows from the side wall W2 toward the side wall W1 in the living space in the lower central portion of the room R. For this reason, the air sent out from the blower outlet 5 is decelerated, and the wind speed of a living space is 0.1 m / s or less. Therefore, cold air does not directly pour into the living space, and an extremely low-speed airflow flows, so that it is possible to prevent the health of the user from being impaired.

<Fifth air flow control>
When the temperature difference between the first and second regions E3 and E4 is set to be larger by the operation of the remote controller 31, the fifth airflow control is performed. In the fifth airflow control, the vertical louvers 12a and 12b and the horizontal louvers 111a to 111d are arranged in the same manner as in the fourth airflow control. The number of rotations of the blower fan 7 is increased, and the wind speed of the blown airflow is increased. Further, the absolute room temperature of the first and second regions E3 and E4 is adjusted by changing the rotational speed of the compressor (not shown).

  For example, when the set temperatures of the first and second regions E3 and E4 are 23 ° C. and 26 ° C., respectively, the rotational speed of the blower fan 7 is set to 150% with respect to the first airflow control, and the compressor (not The number of rotations (shown) is set to 105%. When the set temperatures of the first and second regions E3 and E4 are 22 ° C. and 26 ° C., respectively, the rotational speed of the blower fan 7 is set to 160% with respect to the first airflow control, and the compressor (not The number of rotations (shown) is set to 110%.

  If the wind speed sent out from the blower outlet 5 increases, low-temperature conditioned air reaches farther. Thereby, the temperature difference of 1st, 2nd area | region E3, E4 can be enlarged more. Therefore, by varying the wind speed at the time of blowing, the first and second regions E3 and E4 can be independently temperature controlled to a desired temperature.

<Sixth airflow control>
Next, the sixth airflow control is performed when the regions obtained by dividing the room vertically by the operation unit 31a are set to different temperatures. In FIG. 18, the set temperature of the first area E5 (see FIG. 20) in the upper part of the room is set to 26 ° C. by operating the remote controller 31, and the set temperature of the second area E6 (see FIG. 20) on the far side is set to 24 ° C. The state set to is shown. The first and second regions E5 and E6 are divided by a horizontal plane that divides the central portion of the room R.

  When the cooling operation is started at this set temperature, the vertical louvers 12a and 12b are arranged toward the front as in FIG. The vertical louvers 12a and 12b may be inclined in a range up to about 5 ° with the front facing outward. Further, the horizontal louvers 111a, 111b, 111c, and 111d are arranged as shown in FIG. That is, the upper lateral louvers 111a and 111b are arranged so as to rotate and shield the upper part of the outlet 5. The lower lateral louvers 111c and 111d are set so that the lower end is between the substantially lower direction and the rear lower side with respect to the upper end.

  And the rotation speed of the ventilation fan 7 is set to 80% with respect to the time of 1st airflow control, and conditioned air is sent out from a blower outlet 5 in the substantially downward direction or the downward back. At this time, the blowing wind speed is smaller than the “light wind”. As shown in FIG. 20, the air sent from the blower outlet 5 substantially directly downward or rearwardly descends along the side wall W <b> 1 where the indoor unit 1 is installed, and flows through the floor surface F.

  At this time, if the wind speed at the time of blowing is high, the air that has circulated through the floor F rises and circulates up the side wall W2. The vicinity of W1 and the floor surface F becomes a low temperature. For this reason, the average temperature of the 1st field E5 of the upper part of outdoor unit 1 becomes higher than the average temperature of the 2nd field E6 of the lower part.

  FIG. 21 shows the temperature distribution in the room R during the airflow control described above. The size of the room R is 6 tatami mats (height 2400 mm, width 3600 mm, depth 2700 mm) as described above. FIG. 21 shows the measurement result of the central cross section of the room R indicated by the alternate long and short dash line D shown in FIG.

  According to the figure, the first area E5 on the ceiling side of the room R is about 25 ° C to 27 ° C, and the average temperature is controlled to about 26 ° C. Moreover, the 2nd area | region E6 by the side of the floor F of the room R is about 23 to 25 degreeC, and the average temperature is temperature-controlled at about 24 degreeC. Therefore, the temperature difference between the first and second regions E5 and E6 can be set to about 2 ° C.

  At this time, the air sent out from the blower outlet 5 at a low speed is decelerated when it flows along the side wall W1, and the wind speed of the living space in the lower central part of the room R is 0.1 m / s or less. Further, since the airflow does not reach the upper part of the room R, the upper wind speed is also 0.1 m / s or less. Therefore, cold air does not directly pour into the living space, and an extremely low-speed airflow flows, so that it is possible to prevent the health of the user from being impaired.

<Seventh airflow control>
When the temperature difference between the first and second regions E5 and E6 is set to be larger by the operation of the remote controller 31, the seventh airflow control is performed. In the seventh airflow control, the vertical louvers 12a and 12b and the horizontal louvers 111a to 111d are arranged in the same manner as in the sixth airflow control. The rotational speed of the blower fan 7 is reduced, and the wind speed of the blown airflow is reduced. Further, the absolute room temperature of the first and second regions E5 and E6 is adjusted by changing the rotational speed of the compressor (not shown).

  For example, when the set temperatures of the first and second regions E5 and E6 are 23 ° C. and 26 ° C., respectively, the rotational speed of the blower fan 7 is set to 70% with respect to the first airflow control, and the compressor (not The number of rotations (shown) is set to 105%. When the set temperatures of the first and second regions E5 and E6 are 22 ° C. and 26 ° C., respectively, the rotational speed of the blower fan 7 is set to 60% with respect to the first air flow control, and the compressor (not The number of rotations in the figure is set to 110%.

  If the wind speed of the conditioned air sent out from the blower outlet 5 decreases, the low-temperature conditioned air will not rise further on the opposite side wall W2. Thereby, the temperature difference of 1st, 2nd area | region E5, E6 can be enlarged more. Therefore, the first and second regions E5 and E6 can be independently controlled to a desired temperature by varying the wind speed at the time of blowing.

  According to the present embodiment, the first regions E1, E3, E5 and the second regions E2, E4, E6 divided into the interior can be set to substantially the same temperature, and each can be independently heated to a desired temperature. Can be controlled. Therefore, even when the temperature at which a plurality of users feel comfortable differs, each user can be divided into the first and second regions to satisfy the comfort of each user.

  For example, when a user who prefers an environment of 22 ° C. and a user who prefers an environment of 28 ° C. are in one room in the conventional cooling operation, set the temperature to 28 ° C. according to the latter and cool the former. Continue to apply directly. As a result, the former continues to be directly exposed to the cold and loses physical condition. Also, the set temperature is set to 22 ° C. according to the former, and the latter is made to wear a lot of clothes. As a result, if the latter stays in the room for a long period of time, a so-called “bottom cold” is felt and the physical condition is impaired. The present embodiment can provide a comfortable environment by preventing the physical condition of both from being impaired.

<< Second Embodiment >>
Next, FIG. 22 is a perspective view showing the indoor unit 1 of the air conditioner of the second embodiment. For convenience of explanation, the same reference numerals are given to the same parts as those in the first embodiment shown in FIGS. In the present embodiment, lateral louvers 112a, 112b, and 112c are provided in place of the lateral louvers 111a, 111b, 111c, and 111d of the first embodiment. Other parts are the same as those in the first embodiment.

  The lateral louver 112a is arranged at a position that closes the upper part of the left outlet 5a. The lateral louver 112b is arranged at a position to close the upper part of the right outlet 5b. The lateral louver 112c is arranged at a position that closes the lower part of the air outlet 5. The horizontal louvers 112a, 112b, and 112c have horizontal rotation shafts, and rotate independently by driving a drive motor (not shown). Therefore, the left part of the horizontal louver 112c and the horizontal louver 112a change the vertical direction of the airflow sent from the left outlet 5a. The right part of the horizontal louver 112c and the horizontal louver 112b change the vertical direction of the airflow sent from the right outlet 5b.

  In the case of performing the first airflow control, the vertical louvers 12a and 12b are arranged as shown in FIG. The horizontal louvers 112a, 112b, and 112c are rotated and arranged in the same manner as the horizontal louvers 111a, 111b, and 111c shown in FIG. Thereby, the conditioned air can be sent out during the cooling operation similarly to the first embodiment, and the indoor temperature during the cooling operation can be made uniform.

  When performing the second airflow control, the vertical louvers 12a and 12b are arranged as shown in FIG. The lateral louvers 112b and 112c are arranged in the same manner as in the first airflow control. The horizontal louver 112a is rotated and arranged in the same manner as the horizontal louver 111a shown in FIG. FIG. 23 is a perspective view showing the indoor unit 1 at this time. Accordingly, during the cooling operation, the conditioned air is sent out in the same manner as in the first embodiment, and the first and second regions E1 and E2 (see FIG. 10) divided into the left and right rooms are controlled to different temperatures.

  As described above, the amount of air flowing through the upper portion of the air blowing path 6 is larger than the amount of air flowing through the lower portion. For this reason, even if the lower horizontal louver 112c has the same angle on the left and right, the air flow can be sent in different directions in the vertical direction at the left outlet 5a and the right outlet 5b as in the first embodiment.

  When the third airflow control is performed, the vertical louver 12a and the horizontal louvers 112a to 112c are arranged in the same manner as in the second airflow control. The right vertical louver 12b is disposed with an inclination of 10 ° or more with the front facing inward (left side). In addition, the air volume is increased by increasing the rotational speed of the blower fan 7. Thereby, the conditioned air is sent out during the cooling operation as in the first embodiment, and the temperature difference between the first and second regions E1 and E2 (see FIG. 10) obtained by dividing the room into left and right can be increased. Accordingly, the temperature of the first and second regions E1 and E2 obtained by dividing the room into left and right can be controlled independently.

  When performing the fourth airflow control, the vertical louvers 12a and 12b are arranged as shown in FIG. The horizontal louvers 112a, 112b, and 112c are rotated and arranged in the same manner as the horizontal louvers 111a, 111b, and 111c shown in FIG. Accordingly, during the cooling operation, the conditioned air is sent out in the same manner as in the first embodiment, and the first and second regions E3 and E4 (see FIG. 16) that divide the room forward and backward are controlled to different temperatures.

  When the fifth airflow control is performed, the vertical louvers 12a and 12b and the horizontal louvers 112a, 112b, and 112c are arranged similarly to the fourth airflow control. Then, during the cooling operation, as in the first embodiment, the wind speed is increased to send conditioned air, and the temperature difference between the first and second regions E3 and E4 (see FIG. 16) that divides the room forward and backward is increased. Can do. Therefore, the temperature of the first and second regions E3 and E4 obtained by dividing the room into the front and rear can be controlled independently.

  When performing the sixth airflow control, the vertical louvers 12a and 12b are arranged as shown in FIG. The horizontal louvers 112a, 112b, and 112c are rotated and arranged in the same manner as the horizontal louvers 111a, 111b, and 111c shown in FIG. Accordingly, during the cooling operation, the conditioned air is sent out in the same manner as in the first embodiment, and the first and second regions E5 and E6 (see FIG. 20) obtained by dividing the room vertically are controlled to different temperatures.

  When the seventh airflow control is performed, the vertical louvers 12a and 12b and the horizontal louvers 112a, 112b, and 112c are arranged in the same manner as the sixth airflow control. Then, during the cooling operation, as in the first embodiment, the wind speed is reduced to send conditioned air, and the temperature difference between the first and second regions E5 and E6 (see FIG. 20) obtained by dividing the room up and down is increased. Can do. Therefore, the temperature of the first and second regions E5 and E6 obtained by dividing the room into the front and rear can be controlled independently.

<< Third Embodiment >>
Next, FIG. 24 is a perspective view showing the indoor unit 1 of the air conditioner of the third embodiment. The same parts as those in the first embodiment shown in FIGS. In this embodiment, horizontal louvers 113a and 113b are provided instead of the horizontal louvers 111a, 111b, 111c, and 111d of the first embodiment. Other parts are the same as those in the first embodiment.

  The lateral louver 113a is arranged at a position that closes the upper part of the air outlet 5. The lateral louver 113b is arranged at a position that closes the lower part of the air outlet 5. The horizontal louvers 113a and 113b have horizontal rotation shafts and rotate independently by driving a drive motor (not shown). Further, the lateral louvers 113a and 113b are made of a soft flexible material, and a rotational torque in opposite directions can be applied to the rotary shafts at both ends by a drive motor. Thereby, the horizontal louvers 113a and 113b can be twisted as shown in FIG.

  Therefore, the left part of the horizontal louvers 113a and 113b varies the vertical direction of the airflow sent from the left outlet 5a. The right part of the horizontal louvers 113a and 113b varies the vertical direction of the airflow sent from the right outlet 5b.

  In the case of performing the first airflow control, the vertical louvers 12a and 12b are arranged as shown in FIG. The horizontal louvers 113a and 113b are rotated and arranged in the same manner as the horizontal louvers 111a and 111c shown in FIG. Thereby, the conditioned air can be sent out during the cooling operation similarly to the first embodiment, and the indoor temperature during the cooling operation can be made uniform.

  When performing the second airflow control, the vertical louvers 12a and 12b are arranged as shown in FIG. The right portions of the horizontal louvers 113a and 113b are arranged in the same manner as in the first airflow control. The left portions of the horizontal louvers 113a and 113b are twisted and arranged in the same manner as the horizontal louvers 111a and 111c shown in FIG. FIG. 26 is a perspective view showing the indoor unit 1 at this time. Accordingly, during the cooling operation, the conditioned air is sent out in the same manner as in the first embodiment, and the first and second regions E1 and E2 (see FIG. 10) divided into the left and right rooms are controlled to different temperatures.

  When the third airflow control is performed, the vertical louver 12a and the horizontal louvers 113a and 113b are arranged in the same manner as in the second airflow control. The right vertical louver 12b is disposed with an inclination of 10 ° or more with the front facing inward (left side). In addition, the air volume is increased by increasing the rotational speed of the blower fan 7. Thereby, the conditioned air is sent out during the cooling operation as in the first embodiment, and the temperature difference between the first and second regions E1 and E2 (see FIG. 10) obtained by dividing the room into left and right can be increased. Accordingly, the temperature of the first and second regions E1 and E2 obtained by dividing the room into left and right can be controlled independently.

  When performing the fourth airflow control, the vertical louvers 12a and 12b are arranged as shown in FIG. The horizontal louvers 113a and 113b are rotated and arranged in the same manner as the horizontal louvers 111a and 111c shown in FIG. Accordingly, during the cooling operation, the conditioned air is sent out in the same manner as in the first embodiment, and the first and second regions E3 and E4 (see FIG. 16) that divide the room forward and backward are controlled to different temperatures.

  When the fifth airflow control is performed, the vertical louvers 12a and 12b and the horizontal louvers 113a and 113b are arranged in the same manner as the fourth airflow control. Then, during the cooling operation, as in the first embodiment, the wind speed is increased to send conditioned air, and the temperature difference between the first and second regions E3 and E4 (see FIG. 16) that divides the room forward and backward is increased. Can do. Therefore, the temperature of the first and second regions E3 and E4 obtained by dividing the room into the front and rear can be controlled independently.

  When performing the sixth airflow control, the vertical louvers 12a and 12b are arranged as shown in FIG. The horizontal louvers 113a and 113b are rotated and arranged in the same manner as the horizontal louvers 111a and 111c shown in FIG. Accordingly, during the cooling operation, the conditioned air is sent out in the same manner as in the first embodiment, and the first and second regions E5 and E6 (see FIG. 20) obtained by dividing the room vertically are controlled to different temperatures.

  When the seventh airflow control is performed, the vertical louvers 12a and 12b and the horizontal louvers 113a and 113b are arranged in the same manner as the sixth airflow control. Then, during the cooling operation, as in the first embodiment, the wind speed is reduced to send conditioned air, and the temperature difference between the first and second regions E5 and E6 (see FIG. 20) obtained by dividing the room up and down is increased. Can do. Therefore, the temperature of the first and second regions E5 and E6 obtained by dividing the room into the front and rear can be controlled independently.

<< Fourth Embodiment >>
Next, FIG. 27 is a perspective view showing an installation state of the indoor unit 1 of the air conditioner of the fourth embodiment. For convenience of explanation, the same reference numerals are given to the same parts as those in the first embodiment shown in FIGS. The air conditioner of the present embodiment is a so-called corner air conditioner, and the indoor unit 1 similar to the first embodiment is in a position where the two side walls W5 and W6 adjacent to the room R intersect with the ceiling wall S of the corner L. Installed.

  The figure shows the airflow when the second airflow control is performed. The vertical louver and the horizontal louver of the indoor unit 1 are arranged in the same manner as in the first embodiment. The second airflow (B) sent from the right outlet 5b of the indoor unit 1 flows through the ceiling surface S, descends the side walls W7 and W8 facing the indoor unit 1, and flows through the floor surface F. The first air flow (A) sent from the left outlet 5a of the indoor unit 1 circulates along the left side wall W6 when the indoor unit 1 is viewed from the front. And it arrives at the side wall W7 which opposes the indoor unit 1, and distribute | circulates the floor surface F with a 1st airflow.

  Therefore, as in the first embodiment, the first and second regions E1 and E2 divided by the vertical plane that divides the indoor unit 1 on the diagonal line of the room R are controlled to different temperatures. Further, in other airflow control, the room temperature can be controlled in the same manner as in the first embodiment. Note that the indoor unit 1 of the second and third embodiments may be attached to a position in contact with the ceiling wall S of the corner L to form a corner air conditioner.

  In the first to fourth embodiments, the schematic shape of the room R and the schematic installation position of the indoor unit 1 are displayed in a schematic perspective view on the display unit 31a of the remote controller 31 shown in FIG. The display screen of the display unit 31a is not limited to this, and other screens may be displayed. For example, as shown in FIG. 28, the characters may be expressed as “left 26 ° C., right 24 ° C.”, “front 26 ° C., rear 24 ° C.”, “up 26 ° C., down 24 ° C.”. That is, it is only necessary that the user can easily understand how the two different set temperatures are applied to the first and second regions obtained by dividing the room R. In addition, as shown in FIG. 29, temperature, wind direction, air volume, and the like can be input in more detail by sliding a slide type lid 31d.

  Each airflow control is performed when a command is issued from the remote controller 31 by a user's operation, but may be automatically switched and executed when the room temperature reaches a predetermined condition. Further, a microphone (not shown) connected via a voice recognition unit (not shown) may be provided in the indoor unit 1 and commanded to the control unit. That is, when speaking to the microphone, for example, “Left is cold”, the temperature of the first area divided into the left and right can be controlled to be lower than that of the second area from the state of uniform temperature distribution in the room.

  Further, as shown in FIG. 30, the air conditioner and the communication terminal 36 may be connected via a network 37 such as the Internet. At this time, a server 38 such as a home server may be interposed. The communication terminal 36 includes a personal computer, a telephone, a mobile phone, and the like, and is connected to the network 37 by a wireless mobile communication network, a telephone line, satellite communication, a cable line, and the like.

  The communication terminal 36 is configured to be able to perform operations corresponding to the various key operations of the remote controller 31 shown in FIGS. Thereby, the remote control system of the air conditioner using a network is constructed. Therefore, it is possible to control the temperature of the room by transmitting a command from the communication terminal 36 to the air conditioner, and it is possible to improve the convenience of the air conditioner by remotely operating from the outside.

  Furthermore, you may control an air conditioner based on the information provided via the network 37 from the service organization which provides information, such as a provider. That is, weather information and the like are provided by accessing the air conditioner or the server 38 via the network 37 as part of the service for contract users from the service organization. Based on weather information, the air conditioner is controlled at a low temperature of 2 ° C. on the west side of the room R with respect to the east side on days when the western day is strong. Thereby, the convenience of an air conditioner can be improved more.

  Although the air conditioner according to the present invention has been described above, the present invention is not limited to the above-described embodiment, and can be implemented with appropriate modifications without departing from the spirit of the present invention.

  The present invention can be used for an air conditioner that harmonizes indoor air.

The perspective view which shows the indoor unit of the air conditioner of 1st Embodiment of this invention. Side surface sectional drawing which shows the indoor unit of the air conditioner of 1st Embodiment of this invention The top view which shows the vertical louver of the indoor unit of the air conditioner of 1st Embodiment of this invention The top view which shows the remote controller of the air conditioner of 1st Embodiment of this invention. Side surface sectional drawing which shows arrangement | positioning at the time of the 1st airflow control of the indoor unit of the air conditioner of 1st Embodiment of this invention. The top view which shows arrangement | positioning of the vertical louver at the time of the 2nd airflow control of the indoor unit of the air conditioner of 1st Embodiment of this invention. Side surface sectional drawing which shows arrangement | positioning of the horizontal louver at the time of 2nd airflow control of the indoor unit of the air conditioner of 1st Embodiment of this invention The perspective view which shows arrangement | positioning of the horizontal louver at the time of 2nd airflow control of the indoor unit of the air conditioner of 1st Embodiment of this invention. The perspective view which shows the air sending direction at the time of the 2nd airflow control of the indoor unit of the air conditioner of 1st Embodiment of this invention. The figure which shows the behavior of the airflow in a living room at the time of the 2nd airflow control of the indoor unit of the air conditioner of 1st Embodiment of this invention. The figure which shows the temperature distribution in the cross section D1 of FIG. The figure which shows the temperature distribution in the cross section D2 of FIG. The figure which shows the temperature distribution in the cross section D3 of FIG. The figure which shows the temperature distribution in the cross section D4 of FIG. The top view which shows the display state at the time of 4th airflow control of the remote controller of the air conditioner of 1st Embodiment of this invention. The figure which shows the behavior of the airflow in a living room at the time of 4th airflow control of the indoor unit of the air conditioner of 1st Embodiment of this invention. The figure which shows the temperature distribution in the cross section D of FIG. The top view which shows the display state at the time of 6th airflow control of the remote controller of the air conditioner of 1st Embodiment of this invention. Side surface sectional drawing which shows arrangement | positioning of the horizontal louver at the time of 6th airflow control of the indoor unit of the air conditioner of 1st Embodiment of this invention The figure which shows the behavior of the airflow in a living room at the time of the 6th airflow control of the indoor unit of the air conditioner of 1st Embodiment of this invention. The figure which shows the temperature distribution in the cross section D of FIG. The perspective view which shows the indoor unit of the air conditioner of 2nd Embodiment of this invention. The perspective view which shows arrangement | positioning of the horizontal louver at the time of the 2nd airflow control of the indoor unit of the air conditioner of 2nd Embodiment of this invention. The perspective view which shows the indoor unit of the air conditioner of 3rd Embodiment of this invention. The perspective view which shows the horizontal louver of the indoor unit of the air conditioner of 3rd Embodiment of this invention. The perspective view which shows arrangement | positioning of the horizontal louver at the time of 2nd airflow control of the indoor unit of the air conditioner of 3rd Embodiment of this invention. The figure which shows the behavior of the airflow in a living room at the time of the 2nd airflow control of the indoor unit of the air conditioner of 4th Embodiment of this invention. The top view which shows the other remote controller of the air conditioner of 1st-4th embodiment of this invention. The top view which shows the other remote controller of the air conditioner of 1st-4th embodiment of this invention. The figure which shows the remote control system of the air conditioner using the network of the air conditioner of 1st-4th embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Indoor unit 2 Cabinet 3 Front panel 4 Inlet 5 Outlet 6 Air supply path 7 Blower fan 8 Air filter 9 Indoor heat exchanger 10 Drain pan 111a-111d, 112a-112c, 113a, 113b Horizontal louver 12a, 12b Vertical louver 31 Remote Controller 61 Temperature sensor

Claims (4)

In an air conditioner that sends out conditioned air from an air outlet provided in an indoor unit to the room,
A first vertical airflow direction varying means for vertically varying one of the left and right right air outlets, a second vertical airflow direction varying means for vertically varying the other airflow direction, and the left side A first left and right wind direction variable means for changing the air direction of one of the air outlet and the right side air outlet to the left and right, and a second left and right wind direction changing means for changing the other air direction to the left and right,
During the cooling operation, the first left / right air direction variable means and the first up / down air direction variable means blow air obliquely upward from one of the left outlet and the right outlet, and the second left / right air direction variable means and the second up / down air direction variable. A first operation mode in which air is blown obliquely upward from the other of the left outlet and the right outlet by means to make the room a uniform temperature;
During the cooling operation, the first left and right wind direction changing means and the first up and down wind direction changing means are inclined outwardly in the left and right direction from one of the left outlet and the right outlet to the front and substantially horizontally or downward . together be distributed outlet and along a side wall of the indoor unit side to the left and right and the other of the left outlet and the right air outlet by a second horizontal wind changing means and the second vertical airflow direction changing means and the first air stream vertically have different directions blowing a second airflow towards the ceiling wall of the chamber is circulated along the top wall, first by dividing one room vertical plane dividing the indoor unit to the right and left, the second An air conditioner having a second operation mode in which a temperature difference is provided in the region.   During the cooling operation, the first left and right wind direction varying means and the first up and down wind direction varying means blow air downward from one of the left and right right outlets, and the second left and right wind direction varying means and the second up and down wind direction varying means. The air conditioner according to claim 1, further comprising a third operation mode in which air is blown downward from the other of the left outlet and the right outlet.   A forward plan is formed in the interior of the indoor unit that forms a blower path communicating with the blowout port from a suction port for sucking indoor air, and the blower path is inclined downward as it goes forward to guide the air forward and downward. 3. The air conditioner according to claim 1, wherein the air conditioner has an interior and an upper wall of the air flow path has an inclined surface that is inclined upward as it goes forward from the end of the front guide portion. 4. .   The air conditioner according to any one of claims 1 to 3, wherein the first and second up-and-down air direction varying means are made of the same member having flexibility.

Images