JP6926024B2 - Indoor unit of air conditioner - Google Patents

Description

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

For example, Patent Document 1 discloses a structure in which wall portions rising from a guide surface of a flap are provided at both ends in the longitudinal direction of a flap of an indoor unit of an air conditioner.

International Publication 2014/19590 Pamphlet

In the indoor unit of Patent Document 1, the gap between the side wall of the flap and the air outlet becomes large at the position of the flap that directs the blown air from the air outlet to the lower side of the indoor unit. As a result, surging occurs due to the backflow of the blown air from the gap between the side wall and the blowout port.

An object of the present disclosure is to provide an indoor unit of an air conditioner in which surging is unlikely to occur.

An indoor unit of an air conditioner that solves this problem is heat-exchanged by an indoor unit main body having a suction port and an outlet, a heat exchanger that exchanges heat with air sucked from the suction port, and the heat exchanger. The cross flow fan is provided with a cross flow fan configured to blow out the air from the air outlet, and the cross flow fan is composed of a lower wall, left and right side walls, and an upper wall so that the cross-sectional area is widened toward the end. Further, an outlet flow path for guiding the blown air to the outlet is formed, and the both side walls are provided so as to project from the outlet at least during the air conditioning operation.

According to this configuration, since the air blown out from the outlet is restricted from flowing in the left-right direction of the outlet by the side wall, the outlet can be extended from the outlet. As a result, the static pressure of the blowout channel can be increased, so that the air volume in the blowout channel can be increased. Further, when the ventilation resistance (internal pressure loss) of the indoor unit body becomes high, the backflow of air from both ends in the left-right direction of the air outlet can be suppressed, so that surging is less likely to occur.

In the indoor unit of the air conditioner, it is preferable that the lower wall is provided so as to protrude from the air outlet at least during the air conditioning operation.
According to this configuration, since the lower wall protrudes from the air outlet together with the both side walls, the air blown out from the air outlet is restricted from flowing in the left-right direction and downward from the air outlet by the both side walls and the lower wall. The outlet channel can be extended from the outlet. As a result, the static pressure of the blowout channel can be further increased because the blowout channel having the function of the diffuser becomes longer as compared with the configuration in which both side walls and the lower wall do not protrude from the outlet. The air volume in can be further increased. Further, when the ventilation resistance (internal pressure loss) of the indoor unit body becomes high, it is possible to suppress the backflow of air from both ends in the left-right direction of the air outlet and from below, so that surging is less likely to occur.

In the indoor unit of the air conditioner, it is preferable that the upper wall is provided so as to protrude from the air outlet at least during the air conditioning operation.
According to this configuration, since the upper wall protrudes from the air outlet together with the both side walls, the air blown out from the air outlet is restricted from flowing in the left-right direction and upward from the air outlet by the both side walls and the upper wall. The outlet channel can be extended from the outlet. As a result, the outlet flow path having the function of the diffuser becomes longer as compared with the configuration in which both side walls and the upper wall do not protrude from the outlet, so that the static pressure of the outlet passage can be further increased and the outlet can be blown out. The air volume in the flow path can be further increased. Further, when the ventilation resistance (internal pressure loss) of the indoor unit body becomes high, it is possible to suppress the backflow of air from both ends in the left-right direction of the air outlet and from above, so that surging is less likely to occur.

In the indoor unit of the air conditioner, the outlet is projected from the outlet, and the distance between the left and right sides of the side walls on the downstream side of the outlet in the outlet is the left and right of the outlet. It is preferably formed so as to be smaller than the length in the direction.

According to this configuration, since the cross-sectional area on the downstream side of the outlet in the outlet flow path is small, the wind speed of the air on the downstream side of the outlet in the outlet flow path can be increased. Therefore, the backflow of air from the air outlet can be suppressed, and surging is less likely to occur.

In the indoor unit of the air conditioner, it is possible to change between a stored state in which the component including the side wall constituting the outlet flow path does not protrude from the outlet and a state in which at least the side wall protrudes from the outlet. It is preferable that the moving mechanism is in the protruding state during the air conditioning operation and in the retracted state when the air conditioning operation is stopped.

According to this configuration, surging is less likely to occur because the blowout flow path protrudes from the indoor unit main body during the air conditioning operation, and the blowout flow path is housed in the indoor unit main body while the air conditioner operation is stopped, so that the room is indoors. The aesthetics of the machine will improve.

In the indoor unit of the air conditioner, it is preferable that the moving mechanism moves the component so as to reduce the cross-sectional area of the portion of the air outlet that protrudes from the outlet when surging occurs. ..

According to this configuration, when surging occurs, the cross-sectional area of the air outlet on the downstream side of the air outlet is reduced, so that the air velocity on the downstream side of the air outlet is increased in the air outlet. can do. Therefore, since the backflow of air from the air outlet can be suppressed, surging can be suppressed.

In the indoor unit of the air conditioner, the ratio (H / D) of the height H of the indoor unit body to the outer diameter D of the impeller of the cross flow fan shall be less than 2.2. Is preferable.

According to this configuration, since a cross-flow fan having a large outer diameter of the impeller is used for the indoor unit main body, it is possible to reduce noise and power consumption during air-conditioning operation.

Regarding the indoor unit of the air conditioner of the first embodiment, (a) is a perspective view of the indoor unit in the stored state, and (b) is a perspective view of the indoor unit in the protruding state. Regarding the indoor unit of FIG. 1, (a) is a cross-sectional view of the indoor unit in the stored state, and (b) is a cross-sectional view of the indoor unit in the protruding state. A block diagram showing the electrical configuration of an air conditioner. The flowchart which shows an example of the processing procedure of the movement control executed by the control part of an indoor unit. Regarding the indoor unit of the air conditioner of the second embodiment, (a) is a perspective view of the indoor unit in the stored state, and (b) is a perspective view of the indoor unit in the protruding state. Regarding the indoor unit of FIG. 5, (a) is a cross-sectional view of the indoor unit in the stored state, and (b) is a cross-sectional view of the indoor unit in the protruding state. Regarding the indoor unit of the air conditioner of the third embodiment, (a) is a perspective view of the indoor unit in the stored state, and (b) is a perspective view of the indoor unit in the protruding state. Regarding the indoor unit of FIG. 7, (a) is a cross-sectional view of the indoor unit in the stored state, and (b) is a cross-sectional view of the indoor unit in the protruding state. Regarding the indoor unit of the air conditioner of the fourth embodiment, (a) is a cross-sectional view of the indoor unit, and (b) is an enlarged view of the blowout channel and its periphery of (a). Regarding the indoor unit of the air conditioner of the modified example, (a) is a perspective view of the indoor unit in the stored state, and (b) is a perspective view of the indoor unit in the protruding state. Regarding the indoor unit of the air conditioner of the modified example, (a) is a perspective view of the indoor unit in the stored state, and (b) is a perspective view of the indoor unit in the protruding state. Regarding the indoor unit of the air conditioner of the modified example, (a) is a perspective view of the indoor unit in the stored state, and (b) is a perspective view of the indoor unit in the protruding state. Regarding the indoor unit of the air conditioner of the modified example, (a) is a cross-sectional view of the indoor unit in the stored state, and (b) is a cross-sectional view of the indoor unit in the protruding state. Regarding the indoor unit of the air conditioner of the modified example, (a) is a cross-sectional view of the indoor unit in the stored state, and (b) is a cross-sectional view of the indoor unit in the protruding state. Regarding the indoor unit of the air conditioner of the modified example, (a) is a perspective view of the indoor unit, and (b) is an enlarged view of a part of (a).

(First Embodiment)
The indoor unit 1 of the air conditioner of the first embodiment will be described with reference to FIGS. 1 to 4.
The indoor unit 1 of the present embodiment is a wall-mounted type, and the rear portion thereof is attached to the side wall WL in the room. The indoor unit 1 can perform, for example, a cooling operation for cooling the indoor space and a heating operation for heating the indoor space.

As shown in FIGS. 1 and 2, the indoor unit 1 includes an indoor unit main body 10. The indoor unit main body 10 is formed in a box shape in which the lateral direction (horizontal direction of the indoor unit 1) is the longitudinal direction, and is surrounded by a top surface portion 11, a front surface portion 12, a rear surface portion 13, both side surface portions 14, and a bottom surface portion 15. It has an internal space. The indoor unit 1 is installed on the side wall WL by attaching the rear surface portion 13 to the mounting plate (not shown) of the side wall WL with screws or the like. A suction port 16 is provided on the top surface portion 11 of the indoor unit main body 10, and an air outlet 17 is provided on the bottom surface portion 15. The suction port 16 and the air outlet 17 are provided so that the lateral direction (left-right direction) is the longitudinal direction, respectively. The suction port 16 is formed along the top surface portion 11. The air outlet 17 is formed along the bottom surface portion 15.

As shown in FIG. 2, the indoor unit 1 includes an air filter 21, an indoor heat exchanger 22, a cross flow fan 23, and a flap 24. The air filter 21, the indoor heat exchanger 22, and the cross flow fan 23 are housed in the indoor unit main body 10.

The air filter 21 is detachably attached to the indoor unit main body 10. The air filter 21 collects dust in the indoor air sucked from the suction port 16. The air filter 21 is located between the top surface portion 11 of the indoor unit main body 10 and the indoor heat exchanger 22 in a state of being mounted on the indoor unit main body 10. As a result, the air filter 21 suppresses the adhesion of dust in the indoor air to the surface of the indoor heat exchanger 22.

The indoor heat exchanger 22 has a plurality of fins and a plurality of heat transfer tubes penetrating the plurality of fins. The indoor heat exchanger 22 functions as an evaporator or a condenser depending on the operating state of the indoor unit 1, and exchanges heat between the refrigerant flowing in the heat transfer tube and the air passing through the indoor heat exchanger 22. Let me.

The indoor heat exchanger 22 is provided so that both front and rear ends are bent downward in a side view. The indoor heat exchanger 22 is arranged so as to surround the cross flow fan 23 from above.

The cross flow fan 23 is located substantially in the center of the interior of the indoor unit main body 10. The cross-flow fan 23 has a substantially cylindrical impeller 25 whose lateral direction (horizontal direction) is the longitudinal direction, and a fan case 27 that forms an outlet flow path 26 that communicates with the outlet 17. The blowout flow path 26 is composed of a lower wall 26L, left and right side walls 26S, and an upper wall 26U so that the cross-sectional area increases toward the end. That is, the cross-sectional area of the blowout channel 26 increases toward the outlet 17. Therefore, the blowout flow path 26 has a function of a diffuser.

When the cross-flow fan 23 is rotationally driven, the indoor air taken in from the suction port 16 passes through the indoor heat exchanger 22 and is sent to the cross-flow fan 23. Then, the indoor air sent to the cross flow fan 23 is blown into the room from the outlet 17 through the outlet flow path 26.

The outer diameter of the impeller 25 of the cross-flow fan 23 is defined as the outer diameter D, and the vertical (vertical direction) size of the rear surface portion 13 of the indoor unit main body 10 is defined as the height H of the indoor unit main body 10. In this case, the outer diameter D is preferably 126 mm or more and less than 150 mm. Further, the outer diameter D is more preferably 135 mm or more and less than 150 mm. The height H of the indoor unit main body 10 is preferably 295 mm or less. Further, the height H of the indoor unit main body 10 is more preferably 250 mm or more and 295 mm or less. The ratio (H / D) of the height H of the indoor unit main body 10 to the outer diameter D is preferably less than 2.2. Further, the ratio (H / D) of the height H of the indoor unit main body 10 to the outer diameter D is more preferably 1.6 or more and less than 2.2.

The flap 24 is rotatably provided with respect to the indoor unit main body 10 at the lower edge of the air outlet 17. The flap 24 is formed in a flat plate shape in which the lateral direction (horizontal direction) is the longitudinal direction. The longitudinal length of the flap 24 is approximately equal to the longitudinal length of the outlet 17. The flap 24 is configured so that it can be rotated around the rotation axis C1 by a flap driving motor 28 (see FIG. 3).

The indoor unit 1 of the present embodiment includes a moving mechanism 29 for moving both side walls 26S constituting the blowout flow path 26. More specifically, the side walls 26S include a fixed side wall 26SF and a movable side wall 26SM. The fixed side wall 26SF and the movable side wall 26SM are provided so as to be overlapped with each other in the lateral direction (left-right direction). The movable side wall 26SM is movable so as to slide with respect to the fixed side wall 26SF and protrude from the outlet 17. The moving mechanism 29 moves the movable side wall 26SM. The moving mechanism 29 includes a first motor (not shown) that serves as a drive source, and a rotational linear conversion mechanism (not shown) that converts the rotation of the first motor into a linear motion in a predetermined direction. An example of the moving mechanism 29 is a feed screw mechanism. Further, the moving mechanism 29 is configured so that the movable side wall 26SM can be moved so as to reduce the cross-sectional area between the left and right movable side walls 26SM in a state where the movable side wall 26SM protrudes from the air outlet 17. In one example, the moving mechanism 29 has a second motor (not shown) that rotates the movable side wall 26SM around a rotation axis C2 (see FIG. 2B). As a result, the distance between the left and right movable side walls 26SM on the left and right directions can be changed. In this way, the moving mechanism 29 can switch between a restricted state in which the cross-sectional area between the left and right movable side walls 26SM is reduced and a normal state in which the cross-sectional area between the left and right movable side walls 26SM is not reduced. In one example, in the restricted state, the distance between the left and right movable side walls 26SM on the protruding tip side in the left-right direction is smaller than the length of the air outlet 17 in the left-right direction.

As shown in FIG. 3, the air conditioner includes an outdoor control unit 7 that controls each of the compressor 3, the four-way switching valve 4, the outdoor fan 5, and the expansion valve 6 of the outdoor unit 2. In one example, the outdoor control unit 7 controls the operating frequency (Hz) of the compressor 3, the rotation speed (rpm) of the motor of the outdoor fan 5, and the opening degree of the expansion valve 6, respectively. Further, the outdoor control unit 7 switches between the first state of the four-way switching valve 4 in which the refrigerant circuit (not shown) of the air conditioner is in the cooling cycle and the second state of the four-way switching valve 4 in which the heating cycle is performed.

The indoor unit 1 includes an indoor control unit 30. The indoor control unit 30 includes an arithmetic processing unit that executes a predetermined control program, and a storage unit that stores various control programs and information used for various control processes. The arithmetic processing unit includes, for example, a CPU (Central Processing Unit) or an MPU (Micro Processing Unit). The storage unit includes, for example, a non-volatile memory and a volatile memory. The non-volatile memory includes, for example, a ROM (Read Only Memory), a hard disk, and a flash memory. Volatile memory includes, for example, RAM (Random Access Memory). The indoor control unit 30 may include one or more microcomputers. The outdoor control unit 7 may be configured in the same manner.

The indoor control unit 30 is configured to be able to communicate with the outdoor control unit 7 by wire or wirelessly. Further, the indoor control unit 30 is configured to be able to communicate wirelessly with the remote controller 31. The indoor control unit 30 controls the cross flow fan 23, the flap drive motor 28, and the moving mechanism 29, respectively, based on the operation instruction of the remote controller 31. Further, the indoor control unit 30 communicates the content of the operation instruction of the remote controller 31 with the outdoor control unit 7. Based on the operation instruction of the remote controller 31, the outdoor control unit 7 determines the operating frequency (Hz) of the compressor 3, the rotation speed (rpm) of the motor of the outdoor fan 5, the opening degree of the expansion valve 6, and the four-way switching valve. It controls switching between the first state and the second state of 4.

As shown in FIGS. 1 (a) and 2 (a), the indoor control unit 30 of the present embodiment has a stored state in which the movable side wall 26SM does not protrude from the air outlet 17, and FIGS. 1 (b) and 2 (a). As shown in b), the moving mechanism 29 is controlled so that the movable side wall 26SM switches between the protruding state and the protruding state protruding from the air outlet 17. In one example, the indoor control unit 30 controls the moving mechanism 29 so as to be in a protruding state during the air conditioning operation, and controls the moving mechanism 29 so as to be in a retracted state while the air conditioning operation is stopped. In one example, as shown in FIGS. 1 (b) and 2 (b), the movable side wall 26SM is configured to cover the entire short side (vertical direction) of the air outlet 17 in the protruding state.

Further, the indoor control unit 30 controls the flap drive motor 28 so that the flap 24 covers the air outlet 17, as shown in FIGS. 1A and 2A, while the air conditioning operation is stopped, and performs the air conditioning operation. Inside, as shown in FIGS. 1 (b) and 2 (b), the flap drive motor 28 is controlled so that the flap 24 opens the air outlet 17. As described above, in the indoor unit 1 in which the air conditioning operation is stopped shown in FIGS. 1 (a) and 2 (a), the movable side wall 26SM and the flap 24 are in a state in which the movable side wall 26SM and the flap 24 do not protrude from the indoor unit main body 10, and FIG. 1 (b) shows. In the indoor unit 1 during the air-conditioning operation shown in FIG. 2B, the movable side wall 26SM and the flap 24 are in a state of protruding from the indoor unit main body 10.

The rotation position of the flap 24 can be arbitrarily changed during the air conditioning operation. In one example, the rotation position of the flap 24 can be changed based on the instruction from the remote controller 31.

Further, when surging occurs, the indoor control unit 30 reduces the cross-sectional area between the left and right movable side walls 26SM by the second motor that rotates the movable side wall 26SM around the rotation axis C2 (see FIG. 2B). The moving mechanism 29 is controlled to the restricted state. In the controlled state, the cross-sectional area on the downstream side of the outlet 17 in the outlet channel 26 becomes smaller, so that the wind speed of the indoor air in the outlet channel 26 increases, so surging can be suppressed. Further, the indoor control unit 30 controls the moving mechanism 29 so as to switch from the restricted state to the normal state by the second motor when surging is suppressed. Here, surging is noise generated by the instability of the air volume and pressure of the indoor air blown out from the air outlet 17 and the occurrence of backflow at the air outlet 17 (for example, the noise of "rustling"). .. This surging is likely to occur when the air filter 21 is clogged with dust and the ventilation resistance is increased, or when dew condensation occurs on the indoor heat exchanger 22.

An example of surging detection is performed based on the rotation speed (rpm) of a fan motor (not shown) of the cross-flow fan 23. More specifically, the indoor control unit 30 sets the rotation speed of the fan motor according to the operation instruction of the remote controller 31. The rotation speed of the fan motor set at this time is defined as the set rotation speed. The indoor control unit 30 determines whether or not the rotation speed of the fan motor is within the allowable rotation speed range of a predetermined width centered on the set rotation speed. When the rotation speed of the fan motor is within the permissible rotation speed range, the indoor control unit 30 has a stable rotation speed of the fan motor, so that the air volume and pressure of the indoor air are unlikely to become unstable, so surging occurs. Judge that it is not. On the other hand, in the indoor control unit 30, when the rotation speed of the motor is out of the allowable rotation speed range, the rotation speed of the fan motor is unstable, and the air volume and pressure of the indoor air tend to be unstable, so that surging occurs. It is determined that it is. In the detection of surging, the predetermined width is a width for determining that surging occurs due to variations in the rotation speed of the fan motor, and is preset by a test or the like.

Further, the detection of surging may be performed based on the current supplied to the fan motor of the cross flow fan 23. More specifically, the indoor control unit 30 determines whether or not it is within the allowable current range of a predetermined width centered on the current value corresponding to the set rotation speed. When the current supplied to the fan motor is within the permissible current range, the indoor control unit 30 has a stable air volume and pressure of the indoor air, and the current supplied to the fan motor is stable, so that surging can be performed. Judge that it has not occurred. On the other hand, when the current supplied to the fan motor is out of the allowable current range, the indoor control unit 30 is surging because the air volume and pressure of the indoor air are unstable and the current supplied to the fan motor is not stable. Is determined to have occurred. The predetermined width is a width for determining that surging occurs due to variations in the current supplied to the fan motor, and is preset by a test or the like.

An example of the processing procedure for the movement control of the movement mechanism 29 by the indoor control unit 30 as described above will be described with reference to FIG. This movement control is executed during the period from the start to the end of the air conditioning operation.

The indoor control unit 30 determines whether or not to start the air conditioning operation in step S11. In one example, the indoor control unit 30 determines that the air conditioning operation is started when the remote controller 31 receives the operation start instruction, and determines that the air conditioning operation is not started when the operation start instruction is not received.

When the indoor control unit 30 does not start the air conditioning operation (step S11: NO), the indoor control unit 30 ends the process. In this case, the movable side wall 26SM is maintained in the stored state. On the other hand, when the indoor control unit 30 starts the air conditioning operation (step S11: YES), the indoor control unit 30 is set to the protruding state in step S12. As a result, the movable side wall 26SM is in a state of protruding from the air outlet 17. Then, the indoor control unit 30 determines whether or not surging has occurred in step S13.

When surging occurs (step S13: YES), the indoor control unit 30 sets the second motor of the moving mechanism 29 so that the cross-sectional area between the left and right movable side walls 26SM becomes small in step S14. Control. Then, the indoor control unit 30 determines whether or not to end the air conditioning operation in step S15. In one example, the indoor control unit 30 determines that the air conditioning operation is terminated when the remote controller 31 receives the operation end instruction, and determines that the air conditioning operation is not terminated when the operation end instruction is not received.

When the indoor control unit 30 does not end the air conditioning operation (step S15: NO), the room control unit 30 proceeds to step S13. On the other hand, when the indoor control unit 30 ends the air conditioning operation (step S15: YES), the indoor control unit 30 is set to the stored state in step S16. As a result, the movable side wall 26SM is housed in the indoor unit main body 10.

Further, when surging has not occurred (step S13: NO), the indoor control unit 30 determines in step S17 whether or not the movable side wall 26SM is in the restricted state. When the movable side wall 26SM is in the restricted state (step S17: YES), the indoor control unit 30 changes the movable side wall 26SM to the normal state in step S18, and proceeds to step S15. On the other hand, when the movable side wall 26SM is in the normal state (step S17: NO), the indoor control unit 30 shifts to step S15 while maintaining the movable side wall 26SM in the normal state.

The operation of this embodiment will be described.
The outer diameter D of the impeller 25 of the cross-flow fan 23 is increased for low power and low noise, while the height H of the indoor unit 10 is increased to suppress the decrease in the ease of installation of the indoor unit 10. If not, the region of the indoor unit main body 10 that forms the blowout flow path 26 of the cross flow fan 23 becomes smaller, and the blowout flow path 26 becomes shorter. If the blowing flow path 26 becomes short, the conversion of the dynamic pressure of the indoor air to the static pressure in the blowing flow path 26 is not sufficient, and the air volume and pressure of the cross flow fan 23 decrease.

Further, when the ventilation resistance inside the indoor unit main body 10 increases due to dew condensation on the indoor heat exchanger 22 or clogging of the air filter 21, the wind speed of the indoor air in the outlet flow path 26 decreases, and backflow occurs from the outlet 17. It will be easier. As a result, surging may occur in which the air flow of the indoor air blown out from the cross flow fan 23 becomes unstable due to the backflow of the indoor air from the air outlet 17. In particular, it is known that the wind speed of the indoor air is slower at both ends of the air outlet 17 in the left-right direction than at the central portion of the air outlet 17 in the left-right direction. Therefore, backflow from the air outlet 17 is more likely to occur at both ends of the air outlet 17 in the left-right direction.

In view of these points, in the present embodiment, the movable side wall 26SM is projected from the air outlet 17 during the air conditioning operation. As a result, the outlet flow path 26 can be extended by the length of the movable side wall 26SM. Further, since the movable side wall 26SM extends so as to protrude from the air outlet 17 at both ends in the left-right direction of the air outlet 17, indoor air flows back to the air outlet 17 from the outside of both ends in the left-right direction of the air outlet 17. Is suppressed. As a result, surging can be suppressed, and fluctuations in the air volume and pressure of the cross flow fan 23 can be suppressed.

According to this embodiment, the following effects can be obtained.
(1-1) The movable side wall 26SM of the side wall 26S is provided so as to project from the air outlet 17 at least during the air conditioning operation. According to this configuration, since the indoor air blown out from the outlet 17 is restricted from flowing in the left-right direction of the outlet 17 by the movable side wall 26SM, the outlet flow path 26 can be extended from the outlet 17. As a result, the static pressure of the blowout channel 26 can be increased, so that the air volume in the blowout channel 26 can be increased. Further, when the ventilation resistance (internal pressure loss) inside the indoor unit body 10 becomes high due to, for example, dew condensation on the indoor heat exchanger 22 or clogging of the air filter 21, the backflow of indoor air from both ends of the air outlet 17 is prevented. Since it can be suppressed, surging is less likely to occur.

(1-2) When surging occurs, the moving mechanism 29 makes the distance between the movable side walls 26SM smaller than the length of the air outlet 17 in the left-right direction. According to this configuration, since the cross-sectional area on the downstream side of the outlet 17 in the outlet flow path 26 is smaller, the wind speed of the indoor air on the downstream side of the outlet 17 in the outlet flow path 26 can be increased. Therefore, since the backflow of indoor air from the air outlet 17 can be suppressed, surging can be suppressed.

(1-3) The indoor unit 1 is a moving mechanism that keeps the movable side wall 26SM protruding from the air outlet 17 during the air conditioning operation and keeps the movable side wall 26SM protruding from the air outlet 17 while the air conditioning operation is stopped. 29 is provided. According to this configuration, the movable side wall 26SM protrudes from the indoor unit main body 10 during the air-conditioning operation, so that surging is less likely to occur, and the movable side wall 26SM is housed in the indoor unit main body 10 while the air-conditioning operation is stopped. , The aesthetic appearance of the indoor unit 1 is improved.

(1-4) The indoor unit 1 is configured such that the ratio (H / D) of the height H of the indoor unit main body 10 to the outer diameter D of the impeller 25 of the cross flow fan 23 is less than 2.2. There is. According to this configuration, since the cross flow fan 23 having a large outer diameter D of the impeller 25 is used with respect to the indoor unit main body 10, it is possible to reduce noise and power consumption during operation of the indoor unit 1. ..

(1-5) In the indoor unit 1, the ratio (H / D) of the height H of the indoor unit main body 10 to the outer diameter D of the impeller 25 of the cross flow fan 23 is 1.6 or more and less than 2.2. It is configured as follows. According to this configuration, in addition to the effect of (1-4) above, it is possible to suppress a decrease in the ease of setting of the indoor unit main body 10.

(1-6) The height H of the indoor unit main body 10 is 295 mm or less. As a result, it is possible to suppress a decrease in the ease of installation of the indoor unit main body 10. In particular, the height H of the indoor unit main body 10 is 250 mm or more and 295 mm or less. As a result, the cross-flow fan 23 having a large outer diameter D of the impeller 25 can be used, low power consumption and low noise can be realized, and a decrease in ease of setting of the indoor unit main body 10 can be suppressed.

(Second Embodiment)
The indoor unit 1 of the air conditioner of the second embodiment will be described with reference to FIGS. 5 and 6. The indoor unit 1 of the present embodiment is different from the indoor unit 1 of the first embodiment in that the lower wall 26L together with the side walls 26S of the outlet flow path 26 is projected from the outlet 17 during the air conditioning operation. In the following description, the components common to the indoor unit 1 of the first embodiment are designated by the same reference numerals, and the description thereof may be omitted.

As shown in FIGS. 5B and 6B, the lower wall 26L includes a fixed lower wall 26LF and a movable lower wall 26LM. A flap 24 is rotatably attached to the tip of the movable lower wall 26LM with respect to the movable lower wall 26LM. The fixed lower wall 26LF and the movable lower wall 26LM are provided so as to be superposed on each other in the vertical direction (vertical direction). The movable lower wall 26LM is movable so as to slide with respect to the fixed lower wall 26LF and protrude from the outlet 17.

The moving mechanism 29 of the present embodiment is configured to move the movable side wall 26SM and the movable lower wall 26LM, respectively. In one example, the moving mechanism 29 has a function of sliding the movable side wall 26SM with respect to the fixed side wall 26SF and a function of sliding the movable lower wall 26LM with respect to the fixed lower wall 26LF. The moving mechanism 29 has a first motor, a first rotation linear conversion mechanism that converts the rotation of the first motor into a linear motion of the movable side wall 26SM, and a first rotation linear conversion mechanism that converts the rotation of the first motor into a linear motion of the movable lower wall 26LM. It is equipped with a two-turn straight conversion mechanism. That is, the moving mechanism 29 of the present embodiment moves the movable side wall 26SM and the movable lower wall 26LM by one drive source, respectively.

As shown in FIGS. 5A and 6A, the indoor control unit 30 (see FIG. 3) of the present embodiment is in a stored state in which the movable side wall 26SM and the movable lower wall 26LM do not protrude from the outlet 17, respectively. As shown in FIGS. 5 (b) and 6 (b), the moving mechanism 29 is controlled so that the movable side wall 26SM and the movable lower wall 26LM each switch between a protruding state protruding from the air outlet 17. In one example, the indoor control unit 30 controls the moving mechanism 29 so as to be in a protruding state during the air conditioning operation, and controls the moving mechanism 29 so as to be in a retracted state while the air conditioning operation is stopped.

The movable side wall 26SM is located on the left-right end of the movable lower wall 26LM in the protruding state. The movable side wall 26SM is provided so that a gap is not formed between the movable side wall 26SM and the movable lower wall 26LM in the vertical direction. Further, the movable side wall 26SM is rotatable around the rotation axis C2 between the upper wall 26U and the movable lower wall 26LM.

Further, the relationship between the outer diameter D of the impeller 25 of the cross flow fan 23 of the present embodiment and the height H of the indoor unit main body 10 is the outer diameter D of the impeller 25 of the cross flow fan 23 of the first embodiment and the interior. This is the same as the relationship of the height H of the machine body 10.

According to the present embodiment, in addition to the effects of the first embodiment, the following effects can be obtained.
(2-1) The movable side wall 26SM of the side wall 26S and the movable lower wall 26LM of the lower wall 26L are provided so as to project from the air outlet 17 at least during the air conditioning operation. According to this configuration, the movable side wall 26SM and the movable lower wall 26LM restrict the indoor air blown out from the outlet 17 from flowing in the left-right direction and downward from the outlet 17, so that the outlet 17 is passed through the outlet 17. Can be extended from. As a result, the outlet flow path 26 having the function of a diffuser becomes longer as compared with the configuration in which the side wall 26S and the lower wall 26L do not protrude from the outlet 17, so that the static pressure of the outlet flow path 26 can be further increased. Therefore, the air volume in the blowout channel 26 can be further increased. Further, when the ventilation resistance (internal pressure loss) of the indoor unit main body 10 becomes high, the backflow of indoor air from both ends in the left-right direction of the air outlet 17 and from below can be suppressed, so surging is less likely to occur.

(2-2) The indoor unit 1 is in a protruding state in which the movable side wall 26SM and the movable lower wall 26LM are respectively projected from the air outlet 17 during the air conditioning operation, and the movable side wall 26SM and the movable lower wall 26LM are respectively projected during the air conditioning operation is stopped. A moving mechanism 29 is provided so as to be in a stored state so as not to protrude from the air outlet 17. According to this configuration, the movable side wall 26SM and the movable lower wall 26LM each project from the indoor unit main body 10 during the air-conditioning operation, so that surging is less likely to occur, and the movable side wall 26SM and the movable lower wall 26SM and the movable lower wall are less likely to occur during the air-conditioning operation. By storing each of the 26 LMs in the indoor unit main body 10, the aesthetic appearance of the indoor unit 1 is improved.

(Third Embodiment)
The indoor unit 1 of the air conditioner according to the third embodiment will be described with reference to FIGS. 7 and 8. Compared with the indoor unit 1 of the second embodiment, the indoor unit 1 of the present embodiment has a point in which the upper wall 26U is projected from the air outlet 17 together with the side walls 26S and the lower wall 26L of the outlet flow path 26 during the air conditioning operation. Is different. In the following description, components common to the indoor unit 1 of the second embodiment may be designated by the same reference numerals and the description thereof may be omitted.

The upper wall 26U of the present embodiment includes a fixed upper wall 26UF and a movable upper wall 26UM. The fixed upper wall 26UF and the movable upper wall 26UM are provided so as to be superposed on each other in the vertical direction (vertical direction). The movable upper wall 26UM is movable so as to slide with respect to the fixed upper wall 26UF and protrude from the outlet 17.

The moving mechanism 29 is configured to move the movable side wall 26SM, the movable lower wall 26LM, and the movable upper wall 26UM, respectively. In one example, the moving mechanism 29 has a function of sliding the movable side wall 26SM with respect to the fixed side wall 26SF, a function of sliding the movable lower wall 26LM with respect to the fixed lower wall 26LF, and a movable upper wall 26UM. Has a function of sliding and moving with respect to the fixed upper wall 26UF. The moving mechanism 29 has a first motor, a first rotation linear conversion mechanism that converts the rotation of the first motor into a linear motion of the movable side wall 26SM, and a first rotation linear conversion mechanism that converts the rotation of the first motor into a linear motion of the movable lower wall 26LM. It is provided with a two-rotation straight-ahead conversion mechanism and a third-rotation straight-ahead conversion mechanism that converts the rotation of the first motor into the straight-ahead motion of the movable upper wall 26UM. That is, the moving mechanism 29 of the present embodiment moves the movable side wall 26SM, the movable lower wall 26LM, and the movable upper wall 26UM by one drive source, respectively.

In the indoor control unit 30 (see FIG. 3) of the present embodiment, as shown in FIGS. 7A and 8A, the movable side wall 26SM, the movable lower wall 26LM, and the movable upper wall 26UM are outlets 17 respectively. As shown in FIGS. 7 (b) and 8 (b), a stored state in which the movable side wall 26SM, the movable lower wall 26LM, and the movable upper wall 26UM each protrude from the outlet 17 are shown. The moving mechanism 29 is controlled so as to switch. In one example, the indoor control unit 30 controls the moving mechanism 29 so as to be in a protruding state during the air conditioning operation, and controls the moving mechanism 29 so as to be in a retracted state while the air conditioning operation is stopped.

In the present embodiment, as shown in FIGS. 7 (b) and 8 (b), the movable side wall 26SM covers the entire vertical (vertical direction) of the movable lower wall 26LM and the movable upper wall 26UM in the protruding state. It is configured in. Specifically, the movable side wall 26SM is located between the movable lower wall 26LM and the movable upper wall 26UM at the left-right ends of the movable lower wall 26LM and the movable upper wall 26UM in the protruding state. The movable side wall 26SM is provided so that a gap is not formed between the movable side wall 26SM and the movable lower wall 26LM in the vertical direction. Further, the movable side wall 26SM is rotatable around the rotation axis C2 between the movable upper wall 26UM and the movable lower wall 26LM.

Further, the relationship between the outer diameter D of the impeller 25 of the cross flow fan 23 of the present embodiment and the height H of the indoor unit main body 10 is the outer diameter D of the impeller 25 of the cross flow fan 23 of the first embodiment and the interior. This is the same as the relationship of the height H of the machine body 10.

According to this embodiment, in addition to the effects of the first and second embodiments, the following effects can be obtained.
(3-1) The movable side wall 26SM of the side wall 26S, the movable lower wall 26LM of the lower wall 26L, and the movable upper wall 26UM of the upper wall 26U are provided so as to protrude from the air outlet 17 at least during the air conditioning operation. There is. According to this configuration, the outlet flow path 26 surrounded by the wall portion in the horizontal direction and the vertical direction can be extended from the outlet 17. As a result, the blowout flow path 26 having the function of a diffuser becomes longer as compared with the configuration in which the side wall 26S, the lower wall 26L, and the upper wall 26U do not protrude from the blowout port 17, so that the static pressure of the blowout flow path 26 is increased. It can be further increased, and the air volume in the blowout channel 26 can be further increased. Further, when the ventilation resistance (internal pressure loss) of the indoor unit main body 10 becomes high, it is possible to suppress the backflow of indoor air from both ends, the upper end, and the lower end of the air outlet 17 in the left-right direction, so that surging is further improved. It becomes difficult to occur.

(3-2) The indoor unit 1 is in a protruding state in which the movable side wall 26SM, the movable lower wall 26LM, and the movable upper wall 26UM are each projected from the air outlet 17 during the air conditioning operation, and the movable side wall 26SM, while the air conditioning operation is stopped. A moving mechanism 29 is provided so that the movable lower wall 26LM and the movable upper wall 26UM are not projected from the air outlet 17, respectively. According to this configuration, the movable side wall 26SM, the movable lower wall 26LM, and the movable upper wall 26UM each project from the indoor unit main body 10 during the air-conditioning operation, so that surging is less likely to occur. Further, the movable side wall 26SM, the movable lower wall 26LM, and the movable upper wall 26UM are each housed in the indoor unit main body 10 while the air conditioning operation is stopped, so that the aesthetic appearance of the indoor unit 1 is improved.

(Fourth Embodiment)
The indoor unit 1 of the air conditioner according to the fourth embodiment will be described with reference to FIG. The indoor unit 1 of the present embodiment has a different configuration of the cross flow fan 23 as compared with the indoor unit 1 of the first embodiment. In the following description, the components common to the indoor unit 1 of the first embodiment are designated by the same reference numerals, and the description thereof may be omitted.

As shown in FIGS. 9A and 9B, the indoor unit 1 has a support portion 32 that rotatably supports the flap 24 around the rotation axis C1 as a configuration of the cross flow fan 23. The support portion 32 is attached to the lower end portion of the indoor unit main body 10 near the air outlet 17. That is, it can be said that the support portion 32 constitutes the lower end portion of the indoor unit main body 10. The portion of the support portion 32 on the outlet 17 side constitutes a part of the outlet flow path 26.

As shown in FIG. 9B, the intersection point A when the tangent line VL inscribed in the tongue portion 26A on the upper wall 26U is orthogonal to the flow path forming surface 32X of the support portion 32 and the lower end of the indoor unit main body 10 are formed. The distance from the point B is defined as the distance L, and the outer diameter of the impeller 25 of the cross flow fan 23 is defined as the outer diameter D. In the present embodiment, the ratio (L / D) of the distance L to the outer diameter D is set to less than 0.05. Here, the point B is the most downstream part of the lower wall 26L of the outlet flow path 26. Further, in the present embodiment, as shown in FIG. 9B, the point B is the lowest point of the flow path forming surface 32X of the support portion 32.

In the present embodiment, the movable side wall 26SM is omitted from the side wall 26S. Further, in the present embodiment, the moving mechanism 29 includes a flap driving motor 28 (see FIG. 3). The moving mechanism 29 is configured so as to be changeable between a stored state in which the flap 24 constituting the outlet flow path 26 covers the outlet 17 and a protruding state in which the flap 24 protrudes from the outlet 17. Similar to the first embodiment, the moving mechanism 29 is in a protruding state during the air conditioning operation and is in a retracted state when the air conditioning operation is stopped. That is, as shown by the broken line in FIG. 9A, the flap 24 rotates with respect to the support portion 32 so as to cover the air outlet 17 while the air conditioning operation is stopped. On the other hand, as shown by the solid line in FIG. 9A, the flap 24 rotates with respect to the support portion 32 so as to open the air outlet 17 during the air conditioning operation. The protruding flap 24 faces the flow path forming surface 26X on the upper wall 26U.

According to this embodiment, the following effects can be obtained.
(4-1) The flap 24 forming the lower wall of the outlet flow path 26 is configured to protrude from the outlet 17 at least during the air conditioning operation. Further, the ratio (L / D) of the distance L from the tangent line VL inscribed in the tongue portion 26A of the cross flow fan 23 to the lower end of the indoor unit main body 10 with respect to the outer diameter D of the impeller 25 of the cross flow fan 23 is 0.05. Is less than. According to this configuration, it is possible to realize low power consumption and low noise by suppressing a decrease in the ease of installation of the indoor unit main body 10 and increasing the outer diameter D of the impeller 25 of the cross flow fan 23. Then, the flap 24 protrudes from the outlet 17, so that the length of the diffuser of the outlet flow path 26 can be secured. Therefore, deterioration of the function of the diffuser can be suppressed. Therefore, the deterioration of the performance of the indoor unit 1 can be suppressed.

(4-2) The indoor unit 1 has a moving mechanism 29 that keeps the flap 24 protruding from the air outlet 17 during the air conditioning operation and keeps the flap 24 protruding from the air outlet 17 while the air conditioning operation is stopped. Be prepared. According to this configuration, the flap 24 protrudes from the indoor unit main body 10 during the air-conditioning operation, so that surging is less likely to occur. Further, the flap 24 is housed in the indoor unit main body 10 while the air conditioner operation is stopped, so that the aesthetic appearance of the indoor unit 1 is improved.

(Modification example)
The description of each of the above embodiments is an example of possible embodiments of the indoor unit of the air conditioner according to the present disclosure, and is not intended to limit the embodiments. An indoor unit of an air conditioner according to the present disclosure may take, for example, a form in which a modification of each of the above embodiments shown below and at least two modifications that do not contradict each other are combined. In the following modifications, the parts common to the embodiments of the above embodiments are designated by the same reference numerals as those of the embodiments, and the description thereof will be omitted.

-In the first to third embodiments, at least one of the side wall 26S, the lower wall 26L, and the upper wall 26U constituting the blowout flow path 26 may have a movable wall and a fixed wall. More specifically, the indoor unit 1 may have any of the following configurations (A1) to (A4).
(A1) In the indoor unit 1, both side walls 26S constituting the outlet flow path 26 have a movable side wall 26SM, the upper wall 26U has a movable upper wall 26UM, and the lower wall 26L has a movable lower wall 26LM. Has no configuration. According to this configuration, the movable side wall 26SM and the movable upper wall 26UM protrude from the air outlet 17, so that the indoor air blown out from the air outlet 17 is left and right from the air outlet 17 by the movable side wall 26SM and the movable upper wall 26UM. And because the upward flow is restricted, the outlet flow path 26 can be extended from the outlet 17. As a result, the blowout channel 26 having the function of a diffuser becomes longer as compared with the configuration in which the side wall 26S and the upper wall 26U do not protrude from the outlet 17, so that the static pressure of the blowout channel 26 can be further increased. Therefore, the air volume in the blowout channel 26 can be further increased. Further, when the ventilation resistance (internal pressure loss) of the indoor unit main body 10 becomes high, it is possible to suppress the backflow of air from both ends in the left-right direction of the air outlet 17 and from above, so that surging is less likely to occur.
(A2) In the indoor unit 1, the lower wall 26L constituting the outlet flow path 26 has a movable lower wall 26LM, the upper wall 26U has a movable upper wall 26UM, and both side walls 26S have a movable side wall 26SM. Has no configuration. According to this configuration, since the movable lower wall 26LM protrudes from the outlet 17, the indoor air blown out from the outlet 17 is restricted from flowing downward from the outlet 17 by the movable lower wall 26LM. The outlet flow path 26 can be extended from the outlet 17. As a result, the blowout flow path 26 having a diffuser function becomes longer as compared with the configuration in which the lower wall 26L does not protrude from the blowout port 17, so that the static pressure of the blowout flow path 26 can be further increased, and the blowout flow can be increased. The air volume on the road 26 can be further increased. Further, when the ventilation resistance (internal pressure loss) of the indoor unit main body 10 becomes high, the backflow of air from below the air outlet 17 can be suppressed, so that surging is less likely to occur.
(A3) In the indoor unit 1, the lower wall 26L constituting the outlet flow path 26 has a movable lower wall 26LM, both side walls 26S do not have a movable side wall 26SM, and the upper wall 26U has a movable upper wall 26UM. It has a configuration that it does not have. According to this configuration, since the movable lower wall 26LM protrudes from the outlet 17, the indoor air blown out from the outlet 17 is restricted from flowing downward from the outlet 17 by the movable lower wall 26LM. The outlet flow path 26 can be extended from the outlet 17. As a result, the blowout flow path 26 having a diffuser function becomes longer as compared with the configuration in which the lower wall 26L does not protrude from the blowout port 17, so that the static pressure of the blowout flow path 26 can be further increased, and the blowout flow can be increased. The air volume on the road 26 can be further increased. Further, when the ventilation resistance (internal pressure loss) of the indoor unit main body 10 becomes high, the backflow of air from below the air outlet 17 can be suppressed, so that surging is less likely to occur.
(A4) In the indoor unit 1, the upper wall 26U constituting the outlet flow path 26 has a movable upper wall 26UM, both side walls 26S do not have a movable side wall 26SM, and the lower wall 26L has a movable lower wall 26LM. It has a configuration that it does not have. According to this configuration, since the movable upper wall 26UM protrudes from the outlet 17, the indoor air blown out from the outlet 17 is restricted from flowing upward from the outlet 17 by the movable upper wall 26UM. The outlet flow path 26 can be extended from the outlet 17. As a result, the blowout flow path 26 having a diffuser function becomes longer as compared with the configuration in which the upper wall 26U does not protrude from the blowout port 17, so that the static pressure of the blowout flow path 26 can be further increased, and the blowout flow can be increased. The air volume on the road 26 can be further increased. Further, when the ventilation resistance (internal pressure loss) of the indoor unit main body 10 becomes high, the backflow of air from above the air outlet 17 can be suppressed, so that surging is less likely to occur.

-In the first to third embodiments, the side walls 26S may be changed as in the following configurations (B1) to (B3).
(B1) As shown in FIGS. 10A and 10B, the side wall 26S has a movable side wall 26SM having a shape that spreads in a fan shape around the rotation axis C3. The moving mechanism 29 has a driving motor that rotates the movable side wall 26SM around the rotation shaft C3. The output shaft of the drive motor may be directly connected to the movable side wall 26SM, or may be connected to the movable side wall 26SM via a speed reducer. The moving mechanism 29 moves the movable side wall 26SM so as to switch between the stored state shown in FIG. 10 (a) and the protruding state shown in FIG. 10 (b). As shown in FIG. 10A, in the stored state, the movable side wall 26SM is stored in the indoor unit main body 10, that is, does not protrude from the air outlet 17. As shown in FIG. 10B, in the protruding state, the movable side wall 26SM is in a state of protruding from the indoor unit main body 10, that is, a state of protruding from the air outlet 17. The movable side wall 26SM shown in FIGS. 10A and 10B is provided so as to be adjacent to the end surface of the flap 24 in the lateral direction (left-right direction). Here, it is preferable that no gap is formed between the movable side wall 26SM and the left and right end faces of the flap 24.
(B2) As shown in FIGS. 11A and 11B, the side wall 26S has a movable side wall 26SM that rotates around the rotation axis C4. The moving mechanism 29 has a driving motor that rotates the movable side wall 26SM around the rotation shaft C4. The output shaft of the drive motor may be directly connected to the movable side wall 26SM, or may be connected to the movable side wall 26SM via a speed reducer. The moving mechanism 29 moves the movable side wall 26SM so as to switch between the stored state shown in FIG. 11A and the protruding state shown in FIG. 11B. As shown in FIG. 11A, in the retracted state, the movable side wall 26SM covers the lateral (left-right direction) end of the air outlet 17, that is, does not protrude from the air outlet 17. In the retracted state, the flap 24 is moved so as to cover the air outlet 17 by the flap driving motor 28 (see FIG. 3). In the retracted state, the movable side wall 26SM rotates so as to cover the lateral (left-right direction) end of the flap 24. As shown in FIG. 11B, the protruding state is a state of protruding from the indoor unit main body 10, that is, a state of protruding from the air outlet 17. In one example, when changing from the stored state to the protruding state, the movable side wall 26SM rotates and moves to the outside in the lateral direction (left-right direction) with respect to the flap 24, and then the flap 24 rotates so as to protrude from the air outlet 17.
(B3) As shown in FIGS. 12A and 12B, the side wall 26S has a stretchable movable side wall 26SM. The movable side wall 26SM is configured by a bellows structure. The moving mechanism 29 includes a motor that serves as a drive source, and a rotational linear conversion mechanism that converts the rotation of the motor into a linear motion in the expansion / contraction direction of the movable side wall 26SM. The moving mechanism 29 moves the movable side wall 26SM so as to switch between the stored state shown in FIG. 12 (a) and the protruding state shown in FIG. 12 (b). As shown in FIG. 12A, in the stored state, the movable side wall 26SM is stored in the indoor unit main body 10 by contracting, that is, is not protruding from the air outlet 17. As shown in FIG. 12B, in the protruding state, it is in a state of protruding from the indoor unit main body 10 by extending, that is, a state of protruding from the air outlet 17. The movable side wall 26SM of FIGS. 10A and 10B is provided so as to be adjacent to the flap 24 in the lateral direction (left-right direction). Here, it is preferable that no gap is formed between the movable side wall 26SM and the left and right end faces of the flap 24.

-In the first to third embodiments, the movable side wall 26SM may be configured not to rotate around the rotation axis C2. In this case, the movable side wall 26SM may be configured so that the distance between the movable side walls 26SM in the left-right direction becomes smaller toward the downstream side of the blowout flow path 26.

-In the second and third embodiments, the movable lower wall 26LM of the lower wall 26L is the tip end portion of the fixed lower wall 26LF which is the lower end portion of the indoor unit main body 10 as shown in FIGS. 13 (a) and 13 (b). It may be rotatably provided around the rotation axis C5. The flap 24 is rotatably provided with respect to the tip of the movable lower wall 26LM. As shown in FIG. 13A, the moving mechanism 29 rotates the movable lower wall 26LM in a retracted state so as to cover the air outlet 17 while the air conditioning operation is stopped. In this case, the air outlet 17 is covered by the movable lower wall 26LM and the flap 24. As shown in FIG. 13B, the moving mechanism 29 rotates the movable lower wall 26LM so as to protrude from the air outlet 17 in a protruding state during the air conditioning operation. In this case, the air outlet 17 is not covered by the movable lower wall 26LM and the flap 24. The flap 24 can arbitrarily change its rotational position with respect to the movable lower wall 26LM by the flap driving motor 28 (see FIG. 3) in the protruding state.

-In the third embodiment, as shown in FIGS. 14A and 14B, the movable upper wall 26UM of the upper wall 26U is provided so as to be rotatable around the rotation axis C6 with respect to the tip end portion of the fixed upper wall 26UF. May be done. As shown in FIG. 14A, the moving mechanism 29 rotates the movable upper wall 26UM so as to cover the air outlet 17 in the stored state while the air conditioning operation is stopped. While the air conditioning operation is stopped, the flap 24 also covers the air outlet 17 by the flap drive motor 28 (see FIG. 3). In this way, the air outlet 17 is entirely covered by the movable upper wall 26UM and the flap 24. As shown in FIG. 14B, the moving mechanism 29 rotates the movable upper wall 26UM so as to protrude from the air outlet 17 in a protruding state during the air conditioning operation. In this case, the outlet 17 is not covered by the movable upper wall 26UM and the flap 24.

-In the second embodiment, the moving mechanism 29 may have a first moving mechanism for moving the movable side wall 26SM and a second moving mechanism for moving the movable lower wall 26LM. Each of the first moving mechanism and the second moving mechanism has a motor and a rotational linear conversion mechanism that converts the rotation of the motor into linear motion. Thereby, the movable side wall 26SM and the movable lower wall 26LM can be individually controlled.

-In the second and third embodiments, the moving mechanism 29 may reduce the cross-sectional area on the downstream side of the outlet 17 in the outlet flow path 26 by rotating the flap 24 when surging occurs. good.

In the third embodiment, the moving mechanism 29 includes a first moving mechanism that moves the movable side wall 26SM, a second moving mechanism that moves the movable lower wall 26LM, and a third moving mechanism that moves the movable upper wall 26UM. May have. Each of the first to third movement mechanisms has a motor and a rotation straight-ahead conversion mechanism that converts the rotation of the motor into a straight-ahead motion. Thereby, the movable side wall 26SM, the movable lower wall 26LM, and the movable upper wall 26UM can be individually controlled.

-In the third embodiment, the moving mechanism 29 may have a first moving mechanism for moving the movable side wall 26SM and the movable lower wall 26LM, and a second moving mechanism for moving the movable upper wall 26UM. Each of the first moving mechanism and the second moving mechanism has a motor and a rotational linear conversion mechanism that converts the rotation of the motor into linear motion. Thereby, the movable side wall 26SM, the movable lower wall 26LM, and the movable upper wall 26UM can be individually controlled.

-In the third embodiment, the moving mechanism 29 may have a first moving mechanism for moving the movable side wall 26SM and a second moving mechanism for moving the movable lower wall 26LM and the movable upper wall 26UM. Each of the first moving mechanism and the second moving mechanism has a motor and a rotational linear conversion mechanism that converts the rotation of the motor into linear motion. Thereby, the movable side wall 26SM, the movable lower wall 26LM and the movable upper wall 26UM can be individually controlled.

-In the third embodiment, the moving mechanism 29 may have a first moving mechanism for moving the movable side wall 26SM and the movable upper wall 26UM, and a second moving mechanism for moving the movable lower wall 26LM. Each of the first moving mechanism and the second moving mechanism has a motor and a rotational linear conversion mechanism that converts the rotation of the motor into linear motion. Thereby, the movable side wall 26SM, the movable upper wall 26UM, and the movable lower wall 26LM can be individually controlled.

-In the third embodiment, the outlet flow path 26 is formed so as to protrude from the outlet 17 and the cross-sectional area of the blow-out channel 26 on the downstream side of the outlet 17 is smaller than the cross-sectional area of the outlet 17. May be done. In one example, the cross-sectional area surrounded by the movable side wall 26SM, the movable lower wall 26LM, and the movable upper wall 26UM, which are the constituent elements of the outlet flow path 26, is movable so as to be smaller than the cross-sectional area of the outlet 17. At least one of the side wall 26SM, the movable lower wall 26LM, and the movable upper wall 26UM is moved by the moving mechanism 29. As a result, the wind speed on the downstream side of the blowout flow path 26 can be increased. Therefore, since the backflow of the indoor air from the outlet 17 can be suppressed, surging is less likely to occur.

-In the fourth embodiment, the indoor unit 1 may be changed as follows (C1) to (C4).
(C1) The indoor unit 1 further includes a movable side wall 26SM and a moving mechanism 29 for moving the movable side wall 26SM. In one example, the movable side wall 26SM and the moving mechanism 29 have the same configuration as the movable side wall 26SM and the moving mechanism 29 of the first embodiment. According to this configuration, when the movable side wall 26SM protrudes from the air outlet 17, the indoor air blown out from the air outlet 17 is restricted from flowing in the left-right direction from the air outlet 17 by the movable side wall 26SM and the movable upper wall 26UM. Therefore, the outlet flow path 26 can be extended from the outlet 17. As a result, the outlet flow path 26 becomes longer as compared with the configuration in which the side wall 26S and the upper wall 26U do not protrude from the outlet 17, so that the static pressure of the outlet flow path 26 can be further increased, and the outlet flow path can be increased. The air volume at 26 can be further increased. Further, when the ventilation resistance (internal pressure loss) of the indoor unit main body 10 becomes high, the backflow of air from both ends of the air outlet 17 in the left-right direction can be suppressed, so that surging is less likely to occur.
(C2) The indoor unit 1 further includes a movable lower wall 26LM and a moving mechanism 29 for moving the movable lower wall 26LM. In one example, the movable lower wall 26LM and the moving mechanism 29 have the same configuration as the movable lower wall 26LM and the moving mechanism 29 of the second embodiment. In this case, the flap 24 is rotatably provided at the tip of the movable lower wall 26LM. According to this configuration, since the movable lower wall 26LM protrudes from the outlet 17, the indoor air blown out from the outlet 17 is restricted from flowing downward from the outlet 17 by the movable lower wall 26LM. The outlet flow path 26 can be extended from the outlet 17. As a result, the blowout flow path 26 having a diffuser function becomes longer as compared with the configuration in which the lower wall 26L does not protrude from the blowout port 17, so that the static pressure of the blowout flow path 26 can be further increased, and the blowout flow can be increased. The air volume on the road 26 can be further increased. Further, when the ventilation resistance (internal pressure loss) of the indoor unit main body 10 becomes high, the backflow of air from below the air outlet 17 can be suppressed, so that surging is less likely to occur.
(C3) The indoor unit 1 further includes a movable upper wall 26UM and a moving mechanism 29 for moving the movable upper wall 26UM. In one example, the movable upper wall 26UM and the moving mechanism 29 have the same configuration as the movable upper wall 26UM and the moving mechanism 29 of the third embodiment. According to this configuration, since the movable upper wall 26UM protrudes from the outlet 17, the indoor air blown out from the outlet 17 is restricted from flowing upward from the outlet 17 by the movable upper wall 26UM. The outlet flow path 26 can be extended from the outlet 17. As a result, the blowout flow path 26 having a diffuser function becomes longer as compared with the configuration in which the upper wall 26U does not protrude from the blowout port 17, so that the static pressure of the blowout flow path 26 can be further increased, and the blowout flow can be increased. The air volume on the road 26 can be further increased. Further, when the ventilation resistance (internal pressure loss) of the indoor unit main body 10 becomes high, the backflow of air from above the air outlet 17 can be suppressed, so that surging is less likely to occur.
(C4) The indoor unit 1 is a moving mechanism that moves at least one of the movable side wall 26SM, the movable lower wall 26LM, and the movable upper wall 26UM, and at least one of the movable side wall 26SM, the movable lower wall 26LM, and the movable upper wall 26UM. 29 is further provided. According to this configuration, at least one of the above-mentioned effects (C1) to (C3) can be obtained.

-In the first to fourth embodiments, the moving mechanism 29 may be omitted. In this case, the components constituting the blowout flow path 26 are always in a protruding state. That is, at least one of the side wall 26S, the upper wall 26U, and the lower wall 26L is provided so as to project from the air outlet 17. In one example, in the indoor unit 1 shown in FIG. 15, both side walls 26S, an upper wall 26U, and a lower wall 26L, which are components constituting the outlet flow path 26, are provided so as to project from the outlet 17. In this case, for example, the protrusion 26P in which the distance between the left and right sides of the side walls 26S on the downstream side of the air outlet 17 in the air outlet 26 is smaller than the length in the left and right directions of the air outlet 17 is formed in the side walls 26S. It may be provided in a portion downstream of the air outlet 17. In one example, as shown in FIG. 15, the protrusion 26P has a substantially smaller distance between the upper wall 26U and the lower wall 26L in the left-right direction of both side walls 26S (distance between the left-right directions of the protrusion 26P). It is formed in a triangular pyramid. Further, the surface 26PA on which the protrusions 26P face each other in the left-right direction is formed so that the distance between the protrusions 26P in the left-right direction decreases toward the downstream side of the blowout flow path 26. The shape of the protrusion 26P is formed so that the distance between the left and right sides of the side walls 26S on the downstream side of the outlet 17 in the outlet 26 is smaller than the length of the outlet 17 in the left and right direction. If so, it can be changed arbitrarily.

In the first to third embodiments, the distance between the left and right sides of the side walls 26S on the downstream side of the blowout flow path 26 extended so that the side walls 26S protrude from the air outlet 17 is the blowout flow path 26. It may be provided so as to be always smaller than the distance between the left and right directions of the side walls 26S on the air outlet 17 side (upstream side) of the above. As a result, the wind speed on the downstream side of the blowout flow path 26 can be increased. Therefore, since the backflow of the indoor air from the outlet 17 can be suppressed, surging is less likely to occur.

Although each embodiment and each modification of the indoor unit of the air conditioner of the present disclosure have been described above, various forms and details are various without departing from the purpose and scope of the present disclosure described in the claims. It will be understood that changes are possible.

1 ... Indoor unit 10 ... Indoor unit body 16 ... Suction port 17 ... Air outlet 22 ... Indoor heat exchanger (heat exchanger)
23 ... Cross flow fan 24 ... Flap 25 ... Impeller 26 ... Blowout flow path 26L ... Lower wall 26LF ... Fixed lower wall 26LM ... Movable lower wall 26S ... Left and right side walls 26SF ... Fixed side wall 26SM ... Movable side wall 26U ... Upper wall 26UF ... Fixed upper wall 26UM ... Movable upper wall 29 ... Moving mechanism 26A ... Tongue parts A, B ... Intersection

Claims (10)

An indoor unit main body (10) having a suction port (16) and an air outlet (17),
A heat exchanger (22) that exchanges heat with air sucked from the suction port (16),
A cross-flow fan (23) configured to blow out the air heat-exchanged by the heat exchanger (22) from the outlet (17), and
With
The cross-flow fan (23) is provided with blown air, which is composed of a lower wall (26L), left and right side walls (26S), and an upper wall (26U) so that the cross-sectional area increases toward the end. A blowout channel (26) that guides to (17) is formed.
The both side walls (26S) are provided so as to project from the air outlet (17) at least independently of the upper wall (26U) and the lower wall (26L) during air conditioning operation.
The upper wall (26U) is provided so as to protrude from the air outlet (17) at least during air conditioning operation.
The air conditioner indoor unit (1) extends when the air outlets (26) project from the air outlets (17). The outlet flow path (26) protrudes from the outlet (17) and is a distance between the left and right sides of both side walls (26S) on the downstream side of the outlet (17) in the outlet (26). Is formed so as to be smaller than the length of the outlet (17) in the left-right direction.
The indoor unit of the air conditioner according to claim 1. An indoor unit main body (10) having a suction port (16) and an air outlet (17),
A heat exchanger (22) that exchanges heat with air sucked from the suction port (16),
A cross-flow fan (23) configured to blow out the air heat-exchanged by the heat exchanger (22) from the outlet (17), and
With
The cross-flow fan (23) is provided with blown air, which is composed of a lower wall (26L), left and right side walls (26S), and an upper wall (26U) so that the cross-sectional area increases toward the end. A blowout channel (26) that guides to (17) is formed.
The outlet flow path (26) protrudes from the outlet (17) and is a distance between the left and right sides of both side walls (26S) on the downstream side of the outlet (17) in the outlet (26). Is formed so as to be smaller than the length of the outlet (17) in the left-right direction.
The both side walls (26S) are provided so as to project from the air outlet (17) at least independently of the upper wall (26U) and the lower wall (26L) during air conditioning operation.
The air conditioner indoor unit (1) is extended when the air outlets (26) project from the air outlets (17). A stored state in which the components (26S, 26L, 26U) including the side wall (26S) constituting the outlet flow path (26) do not protrude from the outlet (17), and at least the side wall (26S) is the outlet. It is equipped with a moving mechanism (29) configured to be able to change to a protruding state protruding from the exit (17).
The moving mechanism (29) is in the protruding state during the air conditioning operation, and is in the retracted state when the air conditioning operation is stopped.
The indoor unit of the air conditioner according to any one of claims 1 to 3. The moving mechanism (29) has the components (26S, 26L, 26U) so as to reduce the cross-sectional area of the portion of the outlet flow path (26) protruding from the outlet (17) when surging occurs. ) To move
The indoor unit of the air conditioner according to claim 4. An indoor unit main body (10) having a suction port (16) and an air outlet (17),
A heat exchanger (22) that exchanges heat with air sucked from the suction port (16),
A cross-flow fan (23) configured to blow out the air heat-exchanged by the heat exchanger (22) from the air outlet (17) , a moving mechanism (29), and the like.
With
The cross-flow fan (23) is provided with blown air, which is composed of a lower wall (26L), left and right side walls (26S), and an upper wall (26U) so that the cross-sectional area increases toward the end. A blowout channel (26) that guides to (17) is formed.
The both side walls (26S) are provided so as to project from the air outlet (17) at least independently of the upper wall (26U) and the lower wall (26L) during air conditioning operation.
The outlet flow path (26) is extended when the both side walls (26S) protrude from the outlet (17) .
The moving mechanism (29) is in a stored state in which the components (26S, 26L, 26U) including the side wall (26S) constituting the outlet flow path (26) do not protrude from the outlet (17), and at least. The side wall (26S) is configured to be able to be changed to a protruding state protruding from the outlet (17).
The moving mechanism (29) is in the protruding state during the air conditioning operation, and is in the retracted state when the air conditioning operation is stopped.
The moving mechanism (29) has the components (26S, 26L, 26U) so as to reduce the cross-sectional area of the portion of the outlet flow path (26) protruding from the outlet (17) when surging occurs. ) Is an indoor unit of an air conditioner (1). The lower wall (26L) is provided so as to protrude from the air outlet (17) at least during air conditioning operation.
The indoor unit of the air conditioner according to any one of claims 1 to 6. The ratio (H / D) of the height H of the indoor unit main body (10) to the outer diameter D of the impeller (25) of the cross flow fan (23) is less than 2.2.
The indoor unit of the air conditioner according to any one of claims 1 to 7. The ratio (H / D) of the height H of the indoor unit main body (10) to the outer diameter D of the impeller (25) of the cross flow fan (23) is 1.6 or more.
The indoor unit of the air conditioner according to any one of claims 1 to 8. The outer diameter D of the impeller (25) of the cross flow fan (23) is 126 mm or more and less than 150 mm.
The indoor unit of the air conditioner according to any one of claims 1 to 9.

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