JP6188048B2 - Air conditioner - Google Patents

Description

  The present invention relates to an air conditioner that can convert blown air blown from a blower outlet into an air flow along a ceiling surface of a room.

  2. Description of the Related Art Conventionally, there is an air conditioner that can convert blown air blown from a blower outlet into an air flow along a ceiling surface of a room.

  For example, in an air conditioner disclosed in Patent Document 1 (Japanese Patent Application Laid-Open No. 2003-232531), during the cooling operation, the blown air is made to be an upward airflow along the horizontal louver so as to face the ceiling of the room. Is guiding. And the airflow which reached | attained the ceiling turns into an airflow along a ceiling surface, and goes to the side wall facing an indoor unit. Thereafter, the airflow reaching the side wall is transmitted in the order of the side wall surface and the floor surface, and finally sucked into the indoor unit. Thus, in this air conditioner, the airflow is circulated in the room by forming an airflow along the ceiling surface of the room.

  By the way, when the airflow along the ceiling surface of the room is formed, the airflow is hardly separated from the ceiling surface due to the Coanda effect. For this reason, especially during cooling operation, the airflow along the ceiling surface can be guided to an area far from the air outlet, such as a side wall facing the indoor unit, while being guided to an area near the air outlet, such as around the indoor unit. Cannot be performed, and the overall comfort of the room may be impaired.

  Then, the subject of this invention is providing the air conditioner which can aim at the comfort of the whole room by adjusting the position where the airflow along a ceiling surface peels from a ceiling surface.

The air conditioner according to the first aspect of the present invention is an air conditioner capable of executing a ceiling blowing mode in which the blown air blown from a blower outlet provided at the lower part of the indoor unit is made to be an air flow along the ceiling surface of the room And a refrigerant circuit, a fan, a Coanda blade, a front panel, and a control unit. A compressor, a condenser, an expansion mechanism, and an evaporator are connected to the refrigerant circuit by refrigerant piping. The refrigerant circulates in the refrigerant circuit. The fan forms an air flow of the heat exchanged blown air. Coanda blades are airflow along the outer surface of the self using the Coanda effect, which is a phenomenon that is near the air flow and tries to flow in a direction different from the direction of the flow. Change to The front panel constitutes the front part of the indoor unit, has no suction port, and is provided with a housing part that can accommodate the Coanda blades. In the cooling operation, the control unit adjusts the separation position where the airflow along the ceiling surface is separated from the ceiling surface by changing the temperature of the blown air when the ceiling blowing mode is executed. The Coanda blade is housed in a housing portion provided on the front panel when the operation is stopped, and in the ceiling blowing mode, the Coanda blade moves away from the housing portion by rotating and moves to a position where the rear end of the Coanda blade is in front of the air outlet. and the tangential direction at the front end of the outer surface of the Coanda vane Ri adopt the posture thereof in the forward upward, changing the direction of the outlet air in the ceiling direction.

  In the air conditioner capable of executing the ceiling blowing mode in which the blown air is converted into an air flow along the ceiling surface of the room, the air flow along the ceiling surface is When examining the separation position that peels from the surface, it is possible to adjust the separation position of the airflow along the ceiling surface by changing the temperature of the blown air blown from the blowout port and changing the air density of the blown air I found out that I can do it.

  Therefore, the air conditioner according to the first aspect of the present invention realizes a ceiling blowing mode in which the blown air blown out from the blowout port by the Coanda blade is converted into a Coanda airflow along its outer surface and guided to the ceiling surface. The air flow along the ceiling surface is formed using this Coanda blade. And when performing ceiling blowing mode in air_conditionaing | cooling operation, the peeling position of the airflow along a ceiling surface is adjusted by changing the temperature of blowing air. In this air conditioner, by adjusting the separation position, the airflow along the ceiling surface can be guided not only to an area far from the air outlet but also to an area near the air outlet.

  Thereby, the comfort of the whole room can be aimed at by adjusting the position where the airflow along the ceiling surface peels from the ceiling surface.

  The air conditioner according to a second aspect of the present invention is the air conditioner according to the first aspect, wherein the control unit adjusts the rotational speed of the fan and / or the rotational speed of the compressor to change the temperature of the blown air. Thus, the distance from the outlet to the peeling position is changed. In this air conditioner, by adjusting the rotation speed of the fan and / or the rotation speed of the compressor, the temperature of the blown air is changed, and as a result, the air density of the blown air can be changed.

  The air conditioner according to a third aspect of the present invention is the air conditioner according to the second aspect, wherein the control unit rotates the fan at a constant rotation speed and increases the rotation speed of the compressor, By reducing the temperature, the distance from the outlet to the peeling position is shortened. In this air conditioner, the air density of the blown air is increased by rotating the fan at a constant rotation number and increasing the rotation number of the compressor to lower the temperature of the blown air. As a result, the distance from the outlet to the peeling position can be shortened. Thereby, since the separation position of the airflow along the ceiling surface can be brought close to the air outlet, the air can be guided to an area close to the air outlet.

  An air conditioner according to a fourth aspect of the present invention is the air conditioner according to the second aspect, wherein the control unit lowers the rotational speed of the fan and rotates the compressor at a constant rotational speed, By reducing the temperature, the distance from the outlet to the peeling position is shortened. In this air conditioner, the air density of the blown air is increased by lowering the fan speed and lowering the temperature of the blown air by rotating the compressor at a constant speed. As a result, the distance from the outlet to the peeling position can be shortened. Thereby, since the separation position of the airflow along the ceiling surface can be brought close to the air outlet, the air can be guided to an area close to the air outlet.

  In the air conditioner according to the fifth aspect of the present invention, in the air conditioner according to the first aspect or the second aspect, the control unit adjusts a target evaporation temperature that is a target value of the evaporation temperature of the refrigerant passing through the evaporator. Thus, the temperature of the blown air is changed. In this air conditioner, the temperature of the blown air is changed by adjusting the target evaporation temperature of the refrigerant, and as a result, the air density of the blown air can be changed.

  The air conditioner according to a sixth aspect of the present invention is the air conditioner according to any one of the first to fifth aspects, further comprising a human detection sensor and / or a floor temperature sensor. The human detection sensor detects the presence or absence of a person in a predetermined area of the room. The floor temperature sensor detects the temperature of the floor surface in the room. Moreover, a control part determines a peeling position based on the detection result of a person detection sensor and / or a floor temperature sensor. For this reason, when the air conditioner is provided with a human detection sensor, an area where a person who is a heating element does not exist is determined by determining the separation position as an area where the human detection sensor detects the presence of a person. The air flow along the ceiling surface can be guided to an area where the temperature is considered to be higher. In addition, when the air conditioner is provided with a floor temperature sensor, the separation surface is determined to be an area where the floor surface temperature is higher than the other areas, so that the floor surface temperature is higher than the other areas. The airflow along the ceiling surface can be guided to the area considered to be.

  Thereby, the occurrence of temperature unevenness in the room can be suppressed.

  In the air conditioner according to the first aspect of the present invention, the comfort of the entire room can be achieved.

  In the air conditioner according to the second aspect of the present invention, the air density of the blown air can be changed.

  In the air conditioner according to the third aspect of the present invention, the blown air can be guided to an area close to the blower outlet.

In the air conditioner according to the fourth aspect of the present invention, the blown air can be guided to an area close to the blower outlet.

In the air conditioner according to the fifth aspect of the present invention, the air density of the blown air can be changed.

  In the air conditioner according to the sixth aspect of the present invention, the occurrence of temperature unevenness in the room can be suppressed.

The schematic diagram of the refrigerant circuit with which the air harmony machine concerning one embodiment of the present invention is provided. The control block diagram of the control apparatus with which an air conditioner is provided. The external appearance perspective view of an indoor unit. Sectional drawing of the indoor unit at the time of operation stop. Sectional drawing of the indoor unit at the time of driving | operation. Sectional drawing of the indoor unit at the time of driving | operation. The figure for demonstrating the area where the airflow along a ceiling surface peels from a ceiling surface. The figure for demonstrating the peeling position at the time of setting to different preset temperature. The control block diagram of the control apparatus with which the air conditioner which concerns on the modification B is provided. The figure for demonstrating the area where the airflow along a ceiling surface peels from a ceiling surface in the air conditioner which concerns on the modification B.

  Hereinafter, an air conditioner 10 according to an embodiment of the present invention will be described with reference to the drawings. The following embodiments are specific examples of the present invention and do not limit the technical scope of the present invention.

(1) Whole structure of air conditioner The air conditioner 10 is provided with the outdoor unit 20, the indoor unit 30, and the control apparatus 60 (refer FIG. 2). In addition, as shown in FIG. 1, the air conditioner 10 of this embodiment is a pair type air conditioner in which one outdoor unit 20 and one indoor unit 30 are connected in parallel by a refrigerant pipe. It is. The air conditioner 10 performs various operations including a cooling operation and a heating operation. The air conditioner 10 of the present embodiment is a pair type air conditioner, but is not limited to this, and is a multi-type air conditioner in which a plurality of indoor units 30 are connected to a single outdoor unit 20. It may be a machine.

  In the air conditioner 10, the outdoor unit 20 and the indoor unit 30 are connected by a refrigerant pipe, whereby the vapor compression refrigerant circuit 11 is configured. A compressor 21, an indoor heat exchanger 33, an electric expansion valve 22, and an outdoor heat exchanger 24 are sequentially connected to the refrigerant circuit 11.

(2) Detailed configuration (2-1) Outdoor unit The outdoor unit 20 is installed outdoors, and as shown in FIG. 1, a compressor 21, a four-way switching valve 23, an accumulator 25, an outdoor heat exchanger 24, The outdoor fan 28, the electric expansion valve 22 and the like are housed inside.

  The compressor 21 is an inverter type compressor having a variable rotation speed, and compresses the sucked gas refrigerant.

  The electric expansion valve 22 is a valve for adjusting the refrigerant pressure and the refrigerant flow rate between the indoor heat exchanger 33 and the outdoor heat exchanger 24. In the present embodiment, the electric expansion valve 22 is employed as the expansion mechanism, but the expansion mechanism is not limited to this as long as the mechanism can adjust the refrigerant pressure and the refrigerant flow rate.

  The outdoor heat exchanger 24 is mainly composed of a heat transfer tube that is bent back and forth at both ends in the longitudinal direction, and a plurality of fins inserted from the heat transfer tube. The outdoor heat exchanger 24 functions as an evaporator during heating operation, and functions as a condenser during cooling operation. The outdoor heat exchanger 24 is for exchanging heat with the refrigerant using outdoor air as a heat source, and the outdoor fan 28 generates an air flow in contact with the outdoor heat exchanger 24, so that the outdoor air and the outdoor heat exchanger 24 are generated. Heat can be exchanged with the refrigerant flowing through the heat exchanger 24.

  The outdoor fan 28 is a fan for taking outdoor air into the outdoor unit 20, exchanging heat with the refrigerant in the outdoor heat exchanger 24, and then discharging it to the outside of the outdoor unit 20. Note that the outdoor fan 28 in the present embodiment is a propeller fan driven by a fan motor 28a.

  The four-way switching valve 23 constitutes a switching mechanism that changes the flow path of the refrigerant flowing through the refrigerant circuit 11. The four-way switching valve 23 connects the discharge part 21a of the compressor 21 and the outdoor heat exchanger 24, and connects the indoor heat exchanger 33 and the suction part 21b of the compressor 21 in a first state (FIG. 1). And a second state in which the discharge section 21a of the compressor 21 and the indoor heat exchanger 33 are connected, and the outdoor heat exchanger 24 and the suction section 21b of the compressor 21 are connected (broken line in FIG. 1). The refrigerant circulation direction in the refrigerant circuit 11 is configured to be reversible.

  Further, the accumulator 25 is for separating the liquid refrigerant and the gas refrigerant, and is provided in a refrigerant pipe that connects the suction portion 21b of the compressor 21 and the four-way switching valve 23 in the refrigerant circuit 11. .

(2-2) Indoor unit The indoor unit 30 is a wall-mounted indoor unit installed on the side wall surface of the room. Moreover, the indoor unit 30 accommodates the indoor heat exchanger 33 and the indoor fan 34 inside.

  The indoor heat exchanger 33 is mainly composed of a heat transfer tube that is bent back and forth at both ends in the longitudinal direction and a plurality of fins inserted from the heat transfer tube. The indoor heat exchanger 33 functions as a condenser during heating operation and functions as an evaporator during cooling operation. The indoor heat exchanger 33 is for exchanging heat with the refrigerant using indoor air as a heat source, and the indoor fan 34 generates air flow that contacts the indoor heat exchanger 33, so that the air in the room And the refrigerant flowing through the indoor heat exchanger 33 can exchange heat.

  The indoor fan 34 is a fan for causing the air in the room to be sucked into the indoor unit 30 and for the air after heat exchange with the indoor heat exchanger 33 to be blown into the room. Note that the indoor fan 34 in the present embodiment is a cross-flow fan that generates an air flow in a direction intersecting the rotation axis by being driven to rotate.

(2-3) Control Device As shown in FIG. 2, the control device 60 is connected to various devices included in the outdoor unit 20 and the indoor unit 30, and based on an operation command from the user via the remote controller 80. Then, operation control of various devices according to various operations including cooling operation and heating operation is performed. For example, when performing the cooling operation, the control device 60 switches the four-way switching valve 23 to the first state, and the compressor 21, the outdoor fan 28, the indoor fan 34, and the electric expansion valve 22 are set by the user. It is driven according to the set temperature, the set air volume, the air temperature in the room, etc. On the other hand, when performing the heating operation, the control device 60 switches the four-way switching valve 23 to the second state, and changes the compressor 21, the outdoor fan 28, the indoor fan 34, and the electric expansion valve 22 to the set temperature and It is driven according to the set air volume and the air temperature in the room.

  Moreover, the control apparatus 60 has the execution part 61 which can perform the various operation modes mentioned later.

(3) Detailed Configuration of Indoor Unit FIG. 3 is an external view of the indoor unit 30 when operation is stopped. FIG. 4 is a cross-sectional view of the indoor unit 30 when operation is stopped. FIG. 5 is a cross-sectional view of the indoor unit 30 when the ceiling blowing mode is executed. FIG. 6 is a cross-sectional view of the indoor unit 30 when the ceiling blow mode is viewed from an oblique direction.

  The indoor unit 30 includes a main body casing 31, an indoor heat exchanger 33, an indoor fan 34, horizontal blades 41, and Coanda blades 42.

  The main body casing 31 has a top surface portion 31a, a front panel 31b, a back plate 31c, and a lower horizontal plate 31d, and houses an indoor heat exchanger 33 and an indoor fan 34 therein.

  The top surface part 31a is located in the upper part of the main body casing 31, and a suction port 39 is provided in the front part of the top surface part 31a.

  The front panel 31b constitutes a front portion of the indoor unit 30 and has a flat shape without a suction port. Further, the upper end of the front panel 31b is rotatably supported by the top surface portion 31a, and can operate in a hinged manner. The front panel 31b is provided with a housing portion 37 that can accommodate the Coanda blades 42.

  The indoor heat exchanger 33 and the indoor fan 34 are attached to the bottom frame 36. In addition, the indoor heat exchanger 33 has an inverted V-shape in which both ends are bent downward in a side view, and the indoor fan 34 is located below the indoor heat exchanger 33.

  A blower outlet 35 is provided in the lower part of the main body casing 31. The air outlet 35 is a rectangular opening whose long side is the longitudinal direction of the main casing 31. The outlet 35 is connected to the inside of the main body casing 31 by an outlet channel 38. The blowout flow path 38 is formed along the scroll of the bottom frame 36 from the blowout opening 35. Then, the air in the room is sucked into the indoor fan 34 through the suction port 39 and the indoor heat exchanger 33 by the operation of the indoor fan 34, and blown out from the blower outlet 35 through the blowout flow path 38 from the indoor fan 34.

  Further, a plate-like horizontal blade 41 that is long in the longitudinal direction of the indoor unit 30 is rotatably mounted in the vicinity of the air outlet 35. The horizontal blades 41 are driven by a motor (not shown) and can take a plurality of postures having different inclination angles, thereby changing the vertical flow of the blown air blown from the blower outlet 35.

  A Coanda blade 42 is provided in the vicinity of the air outlet 35 and above the horizontal blade 41. The Coanda blade 42 is a plate-like member that is long in the longitudinal direction of the indoor unit 30. In addition, the Coanda blade | wing 42 is accommodated in the accommodating part 37 provided in the front panel 31b at the time of a driving | operation stop.

  The Coanda blade 42 can be driven by a motor (not shown) to take a plurality of postures having different inclination angles. For example, the Coanda blade 42 moves away from the accommodating portion 37 by rotating and takes a posture in which the front end is inclined upward from the rear end as shown in FIG. 5, or further rotates from the state shown in FIG. The front end and the rear end are taken to be substantially horizontal, or the front end is further rotated and the front end is inclined downward relative to the rear end.

(4) About various operation modes Next, each operation mode performed by the execution part 61 which the control apparatus 60 has is demonstrated.

  Each operation mode executed by the execution unit 61 includes a normal blowing mode, a ceiling blowing mode, and a lower blowing mode. The operation mode can be selected by the user via the remote controller 80 or the like. Further, the operation mode can be controlled so as to be automatically changed according to various operations performed in the air conditioner 10.

(4-1) Normal blowing mode In the normal blowing mode, only the horizontal blades 41 are rotated to adjust the direction of the blowing air. Specifically, the execution unit 61 rotates the horizontal blade 41 to a position where the inner surface 41b of the horizontal blade 41 becomes substantially horizontal, thereby blowing the blown air forward along the inner surface 41b of the horizontal blade 41. Or by turning the horizontal blade 41 until the inner side surface 41b of the horizontal blade 41 is lowered forward from the horizontal, the blown air becomes a forward downward air flow along the inner surface 41b of the horizontal blade 41. Or

(4-2) Ceiling blow mode Coanda (effect) means that if there is a wall near the flow of gas or liquid, it will flow in the direction along the wall even if the direction of flow and the direction of the wall are different. (Asakura Shoten "Dictionary of the Law"). The ceiling blowing mode is a mode using this Coanda effect.

  In the ceiling blowing mode, the direction of the blown air is adjusted by rotating the horizontal blade 41 and the Coanda blade 42. Specifically, the execution unit 61 rotates the horizontal blade 41 until the inner surface 41b of the horizontal blade 41 becomes substantially horizontal. Next, the execution unit 61 rotates the Coanda blade 42 until the outer side surface 42a of the Coanda blade 42 is directed upward. Thereby, the blowing air adjusted to horizontal blowing by the horizontal blades 41 becomes a flow adhering to the outer surface 42a of the Coanda blade 42 due to the Coanda effect, and changes to a Coanda airflow along the outer surface 42a. Therefore, even if the tangent L1 direction at the front end E1 of the horizontal blade 41 is forward blowing, the tangential L2 direction at the front end E2 of the Coanda blade 42 is forward upward blowing, so that the blown air is outside the Coanda blade 42 due to the Coanda effect. The air is blown out in the tangential L2 direction at the front end E2 of the side surface 42a, that is, in the ceiling direction. The blown air blown out in the ceiling direction becomes an air flow along the ceiling surface of the room due to the Coanda effect.

(4-3) Down-blowing mode The down-blowing mode is a mode executed when the posture of the horizontal blade 41 is lower than the tangent L0 of the scroll end F, and rotates the horizontal blade 41 and the Coanda blade 42. The direction of the blown air is adjusted by moving. Specifically, in the down blowing mode, the execution unit 61 rotates the horizontal blade 41 until the inner surface 41b of the horizontal blade 41 faces downward. Next, the execution unit 61 rotates the Coanda blade 42 until the outer surface 42a of the Coanda blade 42 is directed downward. As a result, the blown air passes between the horizontal blades 41 and the Coanda blades 42 and is blown downward.

(5) About operation control of various devices at the time of ceiling blow mode execution When cooling operation is performed and the "ceiling blow mode" is selected by the user, the execution part 61 will have the horizontal blade | wing 41 and the Coanda blade | wing 42. In order to adjust the separation position where the airflow along the ceiling surface separates from the ceiling surface, the temperature of the blown air blown out from the blowout port 35 (hereinafter referred to as the blowout temperature) is changed every predetermined time. Change to automatically. Specifically, the execution unit 61 determines the rotation speed of the indoor fan 34 and the rotation speed of the compressor 21 that are driven based on the set temperature or the like based on the set temperature by adjusting the rotation speed every predetermined time. The blown-out temperature being changed is changed by a predetermined temperature. In addition, the change of the blowing temperature for every predetermined time by the execution part 61 shall be performed in the period (stable period) after the average temperature in a room | chamber has reached preset temperature after starting cooling operation. And the execution part 61 performs control which lowers blowing temperature by raising the rotation speed of the compressor 21, without changing the rotation speed of the indoor fan 34 in this stable period.

  Note that the predetermined time, that is, the time interval for automatically changing the blowing temperature, is appropriately determined by desktop calculation, simulation, experiment, or the like. Moreover, the change of the blowing temperature by the execution part 61 is performed only for a fixed time (for example, 1 minute).

(6) Relationship between the separation position of the airflow along the ceiling surface from the ceiling surface and the blowing temperature FIG. 7 is a diagram showing a predetermined area in the test chamber. FIG. 8 is a diagram for explaining a separation position where the airflow along the ceiling surface C separates from the ceiling surface C when the ceiling blowing mode is executed during the cooling operation. FIG. The peeling position when it is 28 degrees is shown, and (b) shows the peeling position when the set temperature is 20 degrees. 7 and 8 show the result of the ceiling blow mode being executed during the cooling operation for the indoor unit 30 installed on the side wall surface Ha in the test chamber.

  When the blown air is blown out toward the ceiling of the room, an air flow along the ceiling surface of the room is generated due to the Coanda effect. And since this air current is difficult to peel off from the ceiling surface C due to the Coanda effect, the air current can be guided to a far area away from the air outlet 35.

  Here, the present inventor investigated the temperature distribution in the room when the air blown into the air flow along the ceiling surface C of the room during the cooling operation, and found that the area near the air outlet 35 around the indoor unit 30 ( The result that the temperature of area A1) shown in FIG. 7 was higher than the temperature of the area far from the blower outlet 35 (area A2 shown in FIG. 7) was obtained. From this, it was found that the temperature in the area near the air outlet 35 is unlikely to drop when the air blown into the airflow along the ceiling surface C of the room during the cooling operation.

  From this result, the present inventor may bring the separation position where the airflow along the ceiling surface C is peeled off from the ceiling surface C closer to the indoor unit 30 when executing the ceiling blowing mode in which the airflow along the ceiling surface C is formed. If possible, the air flow from the ceiling surface C to the floor surface can be guided to the area close to the indoor unit 30, so that the temperature in the area close to the air outlet 35 can be lowered.

  Therefore, the present inventor first considered a means for reducing the air volume of the blown air by reducing the number of revolutions of the indoor fan 34 as a means for bringing the peeling position closer to the air outlet 35. Therefore, the present inventor has verified whether or not the separation position at which the airflow along the ceiling surface C separates from the ceiling changes according to the rotational speed of the indoor fan 34. As a result, even if only the rotational speed of the indoor fan 34 was lowered, the separation position of the airflow along the ceiling surface C hardly changed.

  Next, the present inventor considered a means for lowering the blowing temperature and increasing the density of the blown air as a means for bringing the peeling position closer to the indoor unit 30. Therefore, in order to verify whether or not the separation position at which the airflow along the ceiling surface C separates from the ceiling changes according to the blowing temperature, the inventor performs cooling operation at different set temperatures, and performs ceiling blowing. The mode was executed. The reason why the verification was attempted by performing the cooling operation at a different set temperature is that the target evaporation temperature of the refrigerant flowing through the indoor heat exchanger 33 is changed by changing the set temperature in the cooling operation. This is because the blowout temperature blown out from the blowout port 35 changes.

  When the ceiling blowing mode is executed in the cooling operation, the side wall surface Ha of the room in which the indoor unit 30 is installed is set when the set temperature is set to 28 degrees and when the set temperature is set to 20 degrees. When the distance from the position to the peeling position was compared, when the set temperature was 28 degrees, the distance from the side wall surface Ha to the peeling position was about 5 m, whereas the set temperature was 20 degrees. In this case, the distance from the side wall surface Ha to the peeling position was about 4 m (see FIG. 8).

  From this result, it is clear that the distance from the side wall surface Ha where the indoor unit 30 is installed to the separation position where the airflow along the ceiling surface C is peeled off from the ceiling surface C can be shortened by lowering the blowing temperature. became. From this, this inventor discovered that the peeling position where the airflow along the ceiling surface C peeled from the ceiling surface C can be adjusted by changing blowing temperature.

  The reason why the separation position of the airflow along the ceiling surface C did not change even when only the rotational speed of the indoor fan 34 was lowered is that the air temperature is compressed so as to be kept constant unless the set temperature is changed. This is probably because the capability control of the machine 21 is automatically performed.

  In the present embodiment, as means for changing the blowing temperature when the ceiling blowing mode is executed during the cooling operation, the rotation speed of the indoor fan 34 is made constant and the rotation speed of the compressor 21 is changed. did.

(7) Features (7-1)
When an airflow along the ceiling surface C is formed during the cooling operation, the airflow along the ceiling surface C is difficult to peel off from the ceiling surface C due to the Coanda effect. For this reason, in the area far from the indoor unit, the airflow along the ceiling surface C, that is, the airflow that peels from the ceiling surface C and travels to the floor surface is guided. The air in the area close to the indoor unit is less likely to be harmonized because the air flow that separates from the floor and is not directed to the floor surface, and as a result, the comfort of the entire room may be impaired.

  Therefore, as a result of examining the separation position where the airflow along the ceiling surface C is peeled off from the ceiling surface C, the present inventor has a low blowing temperature as the distance from the side wall surface Ha where the indoor unit 30 is installed to the separation position. I found it to be shorter. From this, the inventor has found that the separation position where the airflow along the ceiling surface C is separated from the ceiling surface C can be adjusted by changing the blowing temperature and changing the density of the blowing air.

  In the present embodiment, when the “ceiling blowing mode” is selected by the user during the cooling operation, the execution unit 61 automatically sets the blowing temperature determined based on the set temperature. By changing, the separation position of the airflow from the ceiling surface C along the ceiling surface C of the room is adjusted. For this reason, since the airflow along the ceiling surface C can be separated from the position other than the specific position on the ceiling surface C, the airflow directed from the ceiling surface to the floor surface also in the area other than the specific area. Can guide you. Therefore, when the temperature in the room is stable and the blowing temperature becomes high, the blowing temperature is forcibly set when the air flow along the ceiling surface C is guided to an area far from the blowing port 35. By performing the lowering control, the airflow along the ceiling surface C can be separated from the ceiling surface C at a position close to the indoor unit 30 on the ceiling surface C. Therefore, from the indoor unit 30, that is, the air outlet 35. The airflow which peels from the ceiling surface C to the near area and goes to a floor surface can be guide | induced. As a result, since the airflow that peels off the ceiling surface C and travels toward the floor surface can be intermittently guided to an area close to the air outlet 35, the air outlet is less likely to be harmonized in the ceiling air blowing mode in which the separation distance is not adjusted. The air in the area near 35 can be harmonized.

  Thereby, in this air conditioner 10, the comfort of the whole room can be aimed at.

(7-2)
In the present embodiment, as a means for changing the target evaporation temperature of the refrigerant in the indoor heat exchanger 33 to change the blowing temperature, the rotational speed of the indoor fan 34 is made constant and the rotational speed of the compressor 21 is changed. Yes. In the air conditioner 10, the separation position is adjusted by changing the blowout temperature by changing the rotation speed of the indoor fan 34 and changing the rotation speed of the compressor 21.

(7-3)
In this embodiment, when lowering the blowing temperature, control is performed to increase the rotational speed of the compressor 21 without changing the rotational speed of the indoor fan 34. In the air conditioner 10, the distance from the outlet 35 to the separation position is shortened by increasing the rotational speed of the compressor 21 and increasing the air density of the blown air without changing the rotational speed of the indoor fan 34. ing. Thereby, the separation position of the airflow along the ceiling surface C can be brought close to the air outlet 35.

(7-4)
In the present embodiment, the Coanda blade 42 and the horizontal blade 41 cooperate to change the blown air blown from the blower outlet 35 into a Coanda airflow along the outer surface 42a of the Coanda blade 42 and to the ceiling surface C. Guided. For this reason, it is possible to make the blown air into an air flow along the ceiling surface C with a simple configuration. Further, for example, by being along the front panel 31b of the indoor unit 30, it is possible to reduce the possibility that a short circuit will occur as compared with the case where the blown air becomes an airflow along the ceiling surface C.

(8) Modification (8-1) Modification A
In the above embodiment, in order to change the target evaporation temperature of the refrigerant in the indoor heat exchanger 33 and change the blowing temperature, the rotational speed of the indoor fan 34 is made constant and the rotational speed of the compressor 21 is changed. Yes. However, as long as the blowing temperature can be changed, the method for adjusting the evaporation temperature of the refrigerant is not limited to this.

  For example, the execution unit 61 may adjust the target evaporation temperature of the refrigerant by performing control to keep the rotation speed of the compressor 21 constant and change the rotation speed of the indoor fan 34. Specifically, when lowering the blowing temperature, control is performed to rotate the compressor 21 at a constant rotational speed and lower the rotational speed of the indoor fan 34. Moreover, when raising blowing temperature, the compressor 21 is rotated by fixed rotation speed, and the control which raises the rotation speed of the indoor fan 34 is performed. Even if such control is performed, since the evaporation temperature of the refrigerant in the indoor heat exchanger 33 can be adjusted, the blowing temperature can be changed. As a result, the ceiling blowing mode is executed during the cooling operation. In this case, the separation position where the airflow along the ceiling surface C separates from the ceiling can be adjusted.

(8-2) Modification B
FIG. 9 is a control block diagram of the control device 160 included in the air conditioner according to Modification B. In FIG. 9, devices having the same configuration as in the above embodiment are denoted by the same reference numerals as in the above embodiment.

  In the said embodiment, the change of the blowing temperature by the execution part 61 is performed for every predetermined time. For this reason, the peeling position is changed every predetermined time.

  Instead, when the air conditioner includes various sensors, the peeling position may be determined based on the detection results of the various sensors.

  Hereinafter, a case will be described in which the air conditioner includes a human detection sensor 91 that detects the presence or absence of a person in a predetermined area of a room. When the air conditioner includes the human detection sensor 91, when the ceiling blowing airflow is executed during the cooling operation, the air conditioner peels from the ceiling surface C into the area where the human detection sensor 91 detects the presence of a person. The air flow toward the floor surface is guided, or the air flow toward the floor surface after being separated from the ceiling surface C in an area other than the area where the presence of the person is detected by the human detection sensor 91 is guided. In addition, the execution unit 161 may determine the peeling position. Note that, similarly to the execution unit 61 of the above embodiment, the execution unit 161 also performs control for changing the blowing temperature in a stable period when the temperature in the room is stable.

  For example, as shown in FIG. 10, the human detection sensor 91 includes an area A4 that includes a side wall surface Hb that faces the side wall surface Ha on which the indoor unit 130 is installed, and an area A3 that is closer to the indoor unit 130 than the area A4. , When the presence of a person in the area A3 is detected by the person detection sensor 91, the execution unit 161 determines a peeling position in the area A3. May be. In this case, the air temperature along the ceiling surface C is led to the area A4 which is an area far from the air outlet 35 because the temperature in the room is stable and the blowout temperature becomes high. When the presence of a person is detected in the area A3, which is an area close to the air outlet 35, the temperature of the air is lowered, so that the airflow that peels from the ceiling surface C to the area A3 toward the floor surface Can lead. As a result, since there is a person who is a heating element, the temperature of the area A3 considered to be higher than the area A4 can be actively lowered. Thereby, generation | occurrence | production of the temperature nonuniformity in a room can be suppressed. Moreover, the airflow peeled off from the ceiling surface C becomes an airflow like an air shower and goes to the floor surface. For this reason, even if the peeling position is on the person's head, the draft feeling can be suppressed as compared with the case where the airflow blown out from the air outlet 35 directly hits the person.

  On the other hand, when the execution unit 161 detects the presence of a person in the area A3 by the human detection sensor 91, the airflow that the execution unit 161 peels off from the ceiling in the area other than the area A3, that is, in the area A4. When the peeling position is determined so as to be directed, the airflow along the ceiling surface C is less likely to hit the person in the area A3, so that the risk of giving a draft feeling to the person in the room can be reduced. .

  When the air conditioner includes a floor temperature sensor 92 such as a thermopile for detecting the temperature of the floor surface in the room instead of or in addition to the human detection sensor 91, When the ceiling blown airflow is executed during operation, the floor temperature sensor 92 guides the airflow separated from the ceiling surface C and directed to the floor surface in an area where the floor surface temperature is higher than other areas. The execution unit 161 may determine the peeling position.

  For example, when the temperature of the floor surface detected by the floor temperature sensor 92 is higher in the area near the air outlet 35 than in the area far from the air outlet 35, the execution unit 161 peels into the area near the air outlet 35. The position may be determined. In this case, the air temperature along the ceiling surface C is led to an area far from the air outlet 35 by the stable period in which the temperature in the room is stable and the air outlet temperature becomes high. When the temperature of the floor surface in the area close to the air is high, the temperature of the blown air is lowered, so that an air flow that peels from the ceiling surface C to the area close to the air outlet 35 and flows toward the floor surface can be guided. As a result, the temperature of the floor surface in the area close to the air outlet 35 can be actively lowered, so that occurrence of temperature unevenness in the room can be suppressed.

  In the embodiment described above, the blowing temperature based on the set temperature is changed for a certain period of time, so that the peeling position corresponding to the blowing temperature based on the set temperature is changed for a certain period of time. When the sensor 92 is provided, after the temperature of the area with a high floor surface temperature is actively lowered by the execution unit 161 and the temperature of the floor surface is actively lowered, the floor temperature of the area is about the same as that of the other areas. The change of the blowing temperature may be canceled when the temperature reaches Thereby, since the difference of the floor surface temperature in the whole floor surface becomes smaller compared with the case where temperature is actively lowered only for a fixed time, generation | occurrence | production of the temperature nonuniformity in a room can further be suppressed.

(8-3) Modification C
In the said embodiment, the indoor unit 30 is equipped with the Coanda blade | wing 42, and the ceiling blowing mode which makes blowing air into the airflow along the ceiling surface C is performed by cooperating the Coanda blade | wing 42 and the horizontal blade | wing 41. Yes. However, the configuration of the indoor unit 30 is not limited to this as long as the blown air can be an air flow along the ceiling surface C, and the indoor unit 30 may not include the Coanda blades 42.

(8-4) Modification D
Since the air conditioner 10 of the above embodiment is an air conditioner that can perform a heating operation and a cooling operation, the four-way switching valve 23 is connected to the refrigerant circuit 11, but an air conditioner that can perform only a cooling operation. If it is a machine, the four-way switching valve may not be connected to the refrigerant circuit.

(8-5) Modification E
In the said embodiment, the execution part 61 has changed the blowing temperature automatically so that peeling distance may be changed automatically, when performing ceiling blowing mode.

  Instead of this, the user may be able to set whether or not the blowing temperature is automatically changed by the execution unit 61 when the ceiling blowing mode is executed.

(8-6) Modification F
In the said embodiment, when performing the ceiling blowing mode, the execution part 61 changes blowing temperature only by predetermined temperature for every predetermined time, and cancels the control which changes blowing temperature when fixed time passes since changing. . For this reason, when the ceiling blowing mode is executed during the cooling operation, the blowing temperature determined based on the set temperature is changed for a predetermined time every predetermined time. Instead, the execution unit 61 may change the blowing temperature step by step when executing the ceiling blowing mode. The air temperature along the ceiling surface C can be separated from the ceiling surface C at various positions on the ceiling surface C by changing the blowing temperature in stages, so that the air in the room is easily stirred. The possibility of uneven temperature in the room can be reduced.

  The present invention can be applied to an air conditioner capable of forming an airflow along the ceiling surface because the comfort of the entire room can be achieved by adjusting the position where the airflow along the ceiling surface is peeled off from the ceiling surface. Is effective.

DESCRIPTION OF SYMBOLS 10 Air conditioner 11 Refrigerant circuit 21 Compressor 22 Electric expansion valve (expansion mechanism)
24 Outdoor heat exchanger (condenser)
33 Indoor heat exchanger (evaporator)
34 Indoor fans (fans)
35 Outlet 42 Coanda blade 42a Outside surface (surface)
61 Execution unit (control unit)
91 Human detection sensor 92 Floor temperature sensor

JP 2003-232531 A

Claims (6)

An air conditioner capable of executing a ceiling blow mode in which blown air blown from a blower outlet (35) provided at a lower portion of an indoor unit ( 30 ) is made to flow along a ceiling surface (C) of a room. ,
A refrigerant circuit (11) in which a compressor (21), a condenser (24), an expansion mechanism (22), and an evaporator (33) are connected by a refrigerant pipe and the refrigerant circulates;
A fan (34) for forming an air flow of the blown air subjected to heat exchange;
Airflow along the outer side surface (42a) of the blown air by utilizing the Coanda effect, which is a phenomenon that is near the flow of air and tends to flow in a direction different from the direction of the flow. The Coanda vane (42) to turn into
A front panel (31b) that constitutes a front portion of the indoor unit (30), has no suction port, and is provided with a storage portion (37) capable of storing the Coanda blade (42);
When performing the ceiling blowing mode in the cooling operation, by changing the temperature of the blown air, a control unit (61) that adjusts the separation position where the airflow along the ceiling surface is separated from the ceiling surface;
With
The Coanda blade (42) is accommodated in the accommodating portion (37) provided on the front panel (31b) when operation is stopped, and is separated from the accommodating portion (37) by rotating in the ceiling blowing mode. Thus, the rear end of the Coanda blade (42) moves to a position in front of the air outlet (35), and the tangential direction at the front end of the outer surface (42a) of the Coanda blade (42) is forward upward. And change the direction of the blown air to the ceiling ,
Air conditioner (10). The control unit adjusts the rotational speed of the fan and / or the rotational speed of the compressor, and changes the temperature of the blown air, thereby changing the distance from the outlet to the peeling position.
The air conditioner according to claim 1. The controller shortens the distance from the outlet to the peeling position by rotating the fan at a constant rotational speed and increasing the rotational speed of the compressor to lower the temperature of the blown air. To
The air conditioner according to claim 2. The control unit reduces the distance from the outlet to the separation position by lowering the rotation speed of the fan and rotating the compressor at a constant rotation speed to lower the temperature of the blown air. To
The air conditioner according to claim 2. The controller changes the temperature of the blown air by adjusting a target evaporation temperature, which is a target value of the evaporation temperature of the refrigerant passing through the evaporator,
The air conditioner according to claim 1 or 2. A human detection sensor (91) for detecting the presence or absence of a person in a predetermined area of the room, and / or a floor temperature sensor (92) for detecting the temperature of the floor in the room
The control unit determines the peeling position based on a detection result of the human detection sensor and / or the floor temperature sensor.
The air conditioner according to any one of claims 1 to 5.

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