KR100803112B1 - Air conditioner - Google Patents

Abstract

The indoor unit 1 of the air conditioner is installed at the upper part of the wall surface Wl, and the inlet 4 and the outlet 5 are respectively installed at the front and the lower part of the indoor unit 1. The wind direction variable parts 113a, 113b, and 113c which can change a blowout direction from the front horizontal direction to the back downward are arrange | positioned at the blowout opening 5. At the start of heating, the conditioner air is sent out downward on the wall surface Wl. Harmonic air descends along the wall Wl by the Coanda effect, and circulates through the room through the floor F phase. In the stable heating operation state, the airflow paths are narrowed by the wind direction varying units 113b and 113c to reduce the amount of air and send out the conditioner air.

Description

Air Conditioner {AIR CONDITIONER}

The present invention relates to an air conditioner that harmonizes air blown into a cabinet and sends it out to a room.

Conventional air conditioners are shown in Japanese Patent Application No. 2002-266437 and the like. Fig. 28 shows the behavior of the airflow in the room during the heating operation by this air conditioner. The indoor unit 1 of the air conditioner is provided above the side wall Wl. The lower part of the indoor unit 1 is provided with a blowout port (not shown) for sending the harmonic air.

In a startup state in which the room temperature immediately after the start of heating operation rises quickly, it is necessary to quickly circulate the air in the room. Therefore, as shown by the arrow B from the blowout port (not shown), for example, the wind speed "river" ( About 5 to 6 m / sec), and is strongly discharged in the substantially right direction. In the figure, as indicated by the arrows, the inside of the living room R is distributed and returned to the suction port 4 provided in the upper part or the entire part of the indoor unit 1.

When it is detected that the temperature difference between the temperature of the air drawn in from the suction port 4 and the set temperature decreases, the air blowing amount gradually decreases, for example, the rough air is sent at a wind speed of "about" (about 3 to 4 m / sec). Fig. 29 shows the behavior of the airflow in the room in a stable state where this room temperature is stabilized within a predetermined temperature with respect to the set temperature. As indicated by the arrow B 'at the outlet, the roughened air sent out at about the wind speed " about " in the direction immediately below flows into the living room R and returns to the inlet 4. Once the temperature in the living room R drops below the set temperature, the wind speed is increased again. As a result, the room temperature is kept at the set temperature.

In addition, Patent Document 1 discloses an air conditioner capable of varying the direction of the wind direction plate and sending out roughened air toward the direction just below the blower outlet.

Patent Document 1: Japanese Patent No. 3311932

Fig. 30 and Fig. 31 show the temperature distribution in the room when the heating operation is performed with the wind speed " strong " (Fig. 28) and the wind speed " weak " The set temperature of the room temperature is 28 ° C, and the size of the living room R is 6 tatami (height 2400mm, width 3600mm, depth 2400mm). The measurement point measures the central cross section of the room R shown by the dashed-dotted line D in FIGS. 28 and 29 at a total of 48 points of 6 points and 8 points in the height direction and the transverse direction, respectively, at 600 mm intervals.

In the case of the wind speed "strong", as shown in FIG. 28, the warm-up sent from the indoor unit 1 directly downward to the front downwards receives a low specific gravity and receives a strong buoyancy force. For this reason, the wind direction is largely bent forward before reaching the bottom surface. This causes the warmth to flow directly into the living space. For this reason, there is a problem that gives the user an unpleasant feeling when the warmth is continuously poured into the head of the user.

In the case of the wind speed "about", as shown in FIG. 29, the rough air sent directly from the indoor unit 1 to the downward direction has a low wind speed, low specific gravity, and strong buoyancy force. For this reason, it rises as shown by arrow B '. As a result, as shown in Fig. 31, only the upper portion of the living room R can be lukewarm, and the vicinity of the bottom surface cannot be lukewarm. In other words, the feet are cold, the warmth directly facing the head has a problem that the user is significantly unpleasant.

28 and 29, a part of the harmonic air sent out from the indoor unit 1 rises as indicated by arrow B ", and is a so-called short circuit which is blown into the indoor unit 1 immediately without circulating in the living room R. For this reason, as shown in FIGS. 30 and 31, the air around the indoor unit 1 is excessively heated, and the so-called turbulent air E having a temperature near the suction port 4 is 3 ° C or more higher than the set temperature of 28 ° C. There is also a problem that the air conditioning efficiency is lowered.

When turbulent air E is generated by the short circuit when the heating operation is performed at the wind speed "strong" (FIG. 28), it is detected that the temperature of the air blown in by the suction port 4 is close to the set temperature. For this reason, it can be switched to wind speed "about" before the whole living room R becomes sufficiently warm. However, because of the high temperature around the indoor unit 1 due to the turbulent air E, the feet are cold without changing to the wind speed “river”, and the head part continuously gives the user the unpleasant feeling that the warming faces directly.

An object of the present invention is to provide an air conditioner and an air conditioning method capable of realizing improved comfort and improved air conditioning efficiency.

In order to achieve the above object, the present invention provides an air conditioner in which an air conditioner is attached to a wall of an interior to match air blown in at an intake port, and performs heating operation by varying the direction of air from the blowout port. The wind direction of the conditioner air is varied in the substantially horizontal direction or the front upper side and in the direction of approximately the bottom or the rear lower side based on the driving situation or the air conditioner of the room.

According to this configuration, when the heating operation is started by the air conditioner, the air blown in from the suction port is heated up, and is discharged to the front upward, for example, from the blowout port. When the operating condition of the air conditioner or the air conditioner in the room changes, the conditioner air is sent out from the outlet, for example, rearward and downward. Operation condition of an air conditioner having a variable wind direction, the temperature of the air sent from the air conditioner, the temperature of the indoor heat exchanger disposed in the indoor unit, the air volume of the air sent from the air conditioner, the operation of the refrigeration cycle and the compressor operating This includes the frequency, current consumption and power consumption of the air conditioner, and the amount of air blown into the outdoor unit. Moreover, the indoor air condition situation which changes a wind direction includes the indoor air purification degree, indoor ion concentration, etc. based on indoor temperature, indoor humidity, odor component, and amount of dust.

The present invention is also characterized in that, in the air conditioner of the above-described configuration, the wind direction of the conditioner air is varied in the direction immediately below and rearward downward based on the operating condition of the air conditioner or the indoor air conditioner. According to this configuration, when the heating operation is started, the conditioner air is sent out to the front upward, for example, from the outlet. When the operating condition of the air conditioner or the air conditioner in the room changes, the conditioner air is sent out from the outlet, for example, rearward and downward. When the operating condition of the air conditioner or the air conditioner in the room changes, the conditioner air is sent out from the outlet, for example, in a direction substantially directly below.

The present invention is also characterized in that, in the air conditioner of the above-described configuration, the wind direction of the conditioner air is substantially changed in the direction immediately below and forward downward, based on the operating condition of the air conditioner or the indoor air conditioner. According to this configuration, when the heating operation is started, the conditioner air is sent out to the front upward, for example, from the outlet. When the operating condition of the air conditioner or the air conditioner in the room changes, the conditioner air is sent out from the outlet, for example, in a direction substantially directly below. When the operating condition of the air conditioner or the air conditioner in the room changes, the conditioner air is sent out from the outlet, for example, forward and downward.

Furthermore, in the air conditioner of the above-described configuration, when the living room is narrower than a predetermined size, the air direction of the conditioner air is varied substantially in the horizontal direction or the front upper part, and is substantially immediately downward or the rear downward. It is characterized by varying the wind direction of the rough air in the horizontal direction or the front upper side and the front lower side when it is wider than the size of.

According to this structure, when there is little living room, a rough air is sent to the front upwards, for example from a blower outlet. When the operating condition of the air conditioner or the air conditioner in the room changes, the conditioner air is sent out from the outlet, for example, rearward and downward. In the case where the living room is large, harmonized air is sent out from the outlet, for example, upward. When the operating condition of the air conditioner or the air conditioner in the room changes, the conditioner air is sent forward and downward from the outlet.

In addition, the present invention is characterized in that, in the air conditioner of the above-described configuration, the wind speed of the conditioner air is varied based on the operating condition of the air conditioner or the condition of the indoor air conditioner.

According to this configuration, when the heating operation is started, the conditioner air is sent out to the front upward, for example, from the outlet. When the operating condition of the air conditioner or the air conditioner in the room changes, the conditioner air is sent out from the outlet, for example, rearward and downward. When the air conditioner in the room changes in the operating condition of the air conditioner, the air conditioner is blown out at the rear of the air outlet by raising the wind speed, for example.

The present invention is also characterized in that, in the air conditioner of the above-described configuration, the air volume of the conditioner air is varied based on the operating condition of the air conditioner or the condition of the indoor air conditioner.

According to this configuration, when the heating operation is started, the conditioner air is sent out to the front upward, for example, from the outlet. When the operating condition of the air conditioner or the air conditioner in the room changes, the conditioner air is sent out from the outlet, for example, rearward and downward. When the air conditioner in the room changes in the operating condition of the air conditioner, for example, the air volume is lowered at the blower outlet, and the conditioner air is sent out rearward and downward.

The present invention also provides an air conditioner in which the air conditioner is substantially horizontally or forwardly upward when the operating condition of the air conditioner or the indoor air conditioner is the first condition. If the driving condition or the air conditioner in the room is the second condition, the wind direction of the conditioner air is set to the direction immediately below or rearward downward and the driving condition of the air conditioner or the room air conditioner is the third condition. In this case, the wind direction of the conditioner air is set in front of the second condition signal.

Moreover, this invention WHEREIN: The air conditioner of the said structure WHEREIN: A 1st condition is comprised when the blowout temperature is lower than predetermined value, and a 2nd condition is a start-up state in which room temperature rises higher than a predetermined value. It consists of a case and the 3rd conditions are characterized by the case of the stable state with stable room temperature.

According to this configuration, when the extraction temperature is low, the roughened air is sent out substantially in the horizontal direction or the front upward. When the extraction temperature reaches, for example, a predetermined temperature which does not feel cold even when faced directly, and reaches a startup state in which the room temperature rises rapidly, the roughened air is discharged almost immediately downward or backward downward. When the room temperature is brought to a stable state within a predetermined temperature relative to the set temperature, the rough air is blown out slightly forward, for example.

In addition, the present invention is characterized in that an air conditioner having the above-described configuration is provided with a prohibiting means for prohibiting the air to be discharged in the rearward downward direction or in the substantially downward direction.

According to the present invention, since the wind direction of the air conditioner is varied based on the driving condition of the air conditioner or the air conditioner in the room, the user is not faced with hot wind continuously, and the comfort by the user's discomfort is prevented. In addition, in the startup state where the room temperature rises, the hot air is blown out from the outlet toward the rear and down to perform the air conditioning quickly, and easily changes the wind direction, the wind speed, and the air volume in the stable state where the room temperature is stable. Comfort can be improved.

In addition, according to the present invention, the air conditioner, such as the temperature of the air sent out from the outlet, the temperature of the indoor heat exchanger, the operating frequency of the compressor, the current consumption or power consumption of the air conditioner, or the amount of air drawn in the outdoor unit intake Since the wind direction is varied based on the driving situation, it is possible to reduce, for example, high temperature air that is faced to the user by sending the rear side of the roughened air having a high blowing temperature. Therefore, the discomfort of the user can be further reduced.

Further, according to the present invention, since the wind direction is varied based on the air volume sent out from the air outlet, for example, when the air volume is large, the air direction can be sent to the rear and downward to efficiently heat while preventing discomfort to the user. In addition, when the air volume is small, it is possible to send out harmonic air to the front to prevent shortening of the reach and to heat every corner of the room.

Further, according to the present invention, since the wind direction, the wind speed, and the air volume are varied based on the indoor air conditioning situation such as the indoor temperature, the indoor humidity, the indoor ion concentration, the indoor purification degree, and the like, for example, When the difference between the degree of harmony set by the user and the user is large, it is possible to send the conditioner air to the rear more, thereby greatly enlarging the air of the whole room, and to quickly improve the degree of harmony of the air in every corner of the room. This makes it possible to harmonize the air of the entire room in a short time. On the other hand, when the difference between the harmonics of the room and the harmonics set by the user is small, the air is discharged immediately downward to reduce unnecessary rearward airflow, thereby efficiently performing air conditioning.

Further, according to the present invention, there is provided a prohibition means for prohibiting the delivery of air in the rear downward or approximately immediately downward direction, and in the case where there is a wall or an obstacle under the indoor unit, the air discharged downward is returned and blown in from the suction port. It is possible to prevent an increase in the short circuit, and to control the wind direction according to the use situation.

Further, according to the present invention, the wind direction of the roughened air is made to be substantially directly downward or rearward downward in the startup state in which the room temperature rises quickly, and the wind direction of the roughened air is brought forward than the startup state in the stable state, so that the air volume is small. It is possible to reach harmonic air far away in a steady state.

According to the present invention, when the blowout temperature is lower than the predetermined value, since the wind direction of the roughened air is approximately horizontal or forward upward, an air conditioner is obtained in which the low temperature air does not directly face the user and does not feel cold. Can be.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a side sectional view showing a state during second air flow control of an indoor unit of an air conditioner according to a first embodiment of the present invention.

Fig. 2 is a circuit diagram showing a refrigeration cycle of the air conditioner of the first embodiment of the present invention.

Fig. 3 is a block diagram showing the configuration of the air conditioner of the first embodiment of the present invention.

4 is a block diagram showing the configuration of a control unit of the air conditioner of the first embodiment of the present invention.

Fig. 5 is a side sectional view showing a state at the time of first air flow control of the indoor unit of the air conditioner of the first embodiment of the present invention.

Fig. 6 is a side sectional view showing another state in the first air flow control of the indoor unit of the air conditioner of the first embodiment of the present invention.

Fig. 7 is a contour diagram showing the static pressure distribution in the vicinity of the ejection opening in the rear lower ejection state of the indoor unit of the air conditioner of the first embodiment of the present invention.

Fig. 8 is a perspective view showing the behavior of airflow in the living room in the rear lower blow-out state of the indoor unit of the air conditioner of the first embodiment of the present invention.

Fig. 9 is a diagram showing the temperature distribution of the central section of the living room in the rear lower ejection state of the indoor unit of the air conditioner according to the first embodiment of the present invention.

Fig. 10 is a side sectional view showing a state during third air flow control of the indoor unit of the air conditioner of the first embodiment of the present invention.

Fig. 11 is a side sectional view showing another state at the time of the second air flow control of the indoor unit of the air conditioner of the first embodiment of the present invention.

Fig. 12 is a side sectional view showing still another state in the second air flow control of the indoor unit of the air conditioner of the first embodiment of the present invention.

Fig. 13 is a side sectional view showing still another state in the third air flow control of the indoor unit of the air conditioner of the first embodiment of the present invention.

Fig. 14 is a side sectional view showing still another state in the second air flow control of the indoor unit of the air conditioner of the first embodiment of the present invention.

Fig. 15 is a side sectional view showing still another state in the third air flow control of the indoor unit of the air conditioner of the first embodiment of the present invention.

Fig. 16 is a side sectional view showing a state during second air flow control of the indoor unit of the air conditioner of the second embodiment of the present invention.

Fig. 17 is a side sectional view showing a state during the first air flow control of the indoor unit of the air conditioner of the second embodiment of the present invention.

Fig. 18 is a side sectional view showing another state at the time of first air flow control of the indoor unit of the air conditioner of the second embodiment of the present invention.

Fig. 19 is a side sectional view showing a state during third air flow control of the indoor unit of the air conditioner of the second embodiment of the present invention.

Fig. 20 is a side sectional view showing still another state during second air flow control of the indoor unit of the air conditioner of the second embodiment of the present invention.

Fig. 21 is a side sectional view showing still another state in the third air flow control of the indoor unit of the air conditioner of the second embodiment of the present invention.

Fig. 22 is a side sectional view showing a state during the second air flow control of the indoor unit of the air conditioner of the third embodiment of the present invention.

Fig. 23 is a side sectional view showing a state during the first air flow control of the indoor unit of the air conditioner of the third embodiment of the present invention.

Fig. 24 is a side sectional view showing another state at the time of first air flow control of the indoor unit of the air conditioner of the third embodiment of the present invention.

Fig. 25 is a side sectional view showing a state during third air flow control of the indoor unit of the air conditioner of the third embodiment of the present invention.

Fig. 26 is a side sectional view showing another state at the time of third air flow control of the indoor unit of the air conditioner of the third embodiment of the present invention.

Fig. 27 is a perspective view showing the behavior of airflow in the living room in the rear lower blow-out state of the indoor unit of the air conditioner of the third embodiment of the present invention.

Fig. 28 is a perspective view showing the airflow at the time of air volume "strong" in the living room by a conventional air conditioner.

Fig. 29 is a perspective view showing the airflow at the time of air volume " about " in the living room by a conventional air conditioner.

30 is a diagram showing a temperature distribution at the time of air volume "strong" in the cross section of the center part of the living room by the conventional air conditioner.

Fig. 31 is a diagram showing the temperature distribution at the time of air volume " about "

Explanation of the sign

1 indoor unit

2 cabinet

3 front panel

4 inlet

5 outlet

6 ventilation path

7 blower fan

8 air filter

9 indoor heat exchanger

10 drain pan

12 Bell Louver

25 Eddie

60 control unit

61 temperature sensor

62 compressor

63 four-way exchange valve

64 outdoor heat exchanger

65 blower fan

66 stop mechanism

67 Refrigerant Piping

68 refrigeration cycle

71 CPU

72 input circuit

73 output circuit

74 memory

90 Fixed Pressure

98 virtual plane

113a, 113b, 113c, 114a, 114b, 115a, 115b wind direction variable part

EMBODIMENT OF THE INVENTION Below, the Example of this invention is described with reference to drawings. For convenience of explanation, the same reference numerals are attached to the same parts as the conventional examples shown in Figs. 28 and 29 described above in the following embodiments.

<First Embodiment>

Fig. 1 is a side sectional view showing the air conditioner of the first embodiment (point D is shown in Fig. 8 to be described later). In the indoor unit 1 of the air conditioner, the main body is held by the cabinet 2, and the cabinet 2 is provided with a detachable front panel 3 provided with a suction port 4 at the front side and the front side.

The cabinet 2 is provided with a claw (not shown) on the rear side and supported by engaging the claw with a mounting plate (not shown) provided on the side wall Wl of the living room. A blowout port 5 is provided at a gap between the lower end of the front panel 3 and the lower end of the cabinet 2. The outlet 5 is formed in a substantially rectangular shape extending in the width direction of the indoor unit 1, and is provided toward the front lower side.

In the indoor unit 1, a blowing path 6 is formed in communication with the intake port 4 from the intake port 4. The blowing fan 7 which supplies air is arrange | positioned in the blowing path 6. As the blowing fan 7, for example, a cross flow fan can be used. The blowing path 6 has a front guide portion 6a for guiding the air blown out by the blowing fan 7 forward and downward. The front guide portion 6a has a longitudinal louver capable of changing the extraction angle in the left and right directions ( 12) is installed. Moreover, the upper wall of the ventilation path 6 is an inclined surface which inclines upwards toward the front from the end of the front guide part 6a.

The air outlet variable parts 113a, 113b, and 113c which are rotatably supported by the blower outlet 5 are provided. The wind direction variable part 113c extends to the lower wall of the front guide part 6a, and is supported by the cabinet 2 by the rotating shaft 113f which rotates by the drive of a drive motor (not shown). The wind direction variable part 113a is rotatably supported by the rotating shaft 113d which is arrange | positioned at the upper part of the blowout opening 5, and rotates by a drive motor (not shown).

The wind direction variable part 113b is rotatably supported by the rotating shaft 113e which is arrange | positioned under the blowout port 5, and rotates by a drive motor (not shown). The wind direction variable parts 113a and 113b rotate independently by the driving of each drive motor, and change the direction to change the wind direction.

Further, the wind direction variable portions 113b and 113c are curved in cross-sectional shape, one surface being formed as a convex curved surface, and the other surface is formed as a concave curved surface. The wind direction variable portion 113a is formed of a convex curved surface where one surface (left side of the drawing) is substantially flat and the other surface (right side of the drawing) is smooth, and the vicinity of the central portion is supported by the axis of rotation 113d. It is. Moreover, the state of the same figure shows the case where the roughened air is sent from the blowout port 5 mentioned later in detail toward the rear downward.

The air filter 8 which collects and removes the dust contained in the air absorbed from the suction port 4 is provided in the position which opposes the front panel 3. An indoor heat exchanger 9 is disposed between the blowing fan 7 and the air filter 8 of the blowing path 6. The indoor heat exchanger 9 is connected to a compressor 62 (see Fig. 2) arranged outdoors, and the refrigeration cycle is driven by the compressor 62.

When cooling by the operation of the refrigeration cycle, the indoor heat exchanger (9) is cooled to a lower temperature than the ambient temperature. At the time of heating, the indoor heat exchanger 9 is heated to a higher temperature than the ambient temperature. Furthermore, a temperature sensor 61 is provided between the indoor heat exchanger 9 and the air filter 8 for detecting the temperature of the absorbed air. On the side of the indoor unit 1, a control unit 60 (see Fig. 3) for controlling the driving of the air conditioner is provided. In the lower part before and after the indoor heat exchanger 9, the drain pan 10 which collects the dew which fell from the indoor heat exchanger 9 at the time of cooling or dehumidification is provided.

로 구성되는 플라스틱 이온을 생성하고, 부전압의 경우는 주로In the front drain pan 10, the ion generating device 30 is provided with the discharge surface 30a facing the blowing path 6. The ions generated at the discharge surface 30a of the ion generating device 30 are discharged into the blowing path 6 and are taken out from the blowout port 5 into the room. The ion generating device 30 has a discharge electrode, and is mainly used when the applied voltage is a constant voltage by corona discharge.

To produce plastic ions, and in the case of negative voltage

로 구성되는 마이너스 이온을 생성한다(n,m은 정수).

Generate negative ions consisting of (n, m is an integer).

는 미생물의 표면에서 응집하고, 공기 중의 미생물 등의 부유균을 둘러싼다. 그리고, 식(1)∼(3)에 나타내는 바와 같이, 충돌에 의해 활성종으로 되는

(수산기 라디칼)이나 H₂O₂(과산화수소)를 부유균의 표면상에 생성한다( n',m'은 정수). 이것에 의해 부유균을 파괴하여 살균을 행한다.

Aggregates on the surface of microorganisms and surrounds floating bacteria such as microorganisms in the air. And as shown to Formula (1)-(3), it becomes an active species by a collision

(Hydroxyl radical) or H ₂ O ₂ (hydrogen peroxide) are produced on the surface of the floating bacteria (n ', m' is an integer). As a result, the airborne bacteria are destroyed and sterilized.

…(1)

… (One)

이온 발생 장치(30)는 사용 목적에 따라, 플러스 이온에 비해 마이너스 이온을 많이 발생시키는 모드, 마이너스 이온에 비해 플러스 이온을 많이 발생시키는 모드, 및 플러스 이온과 마이너스 이온의 양방을 대략 동량의 비율로 발생시키는 모드의 전환이 가능하게 되어 있다.

According to the purpose of use, the ion generating device 30 generates a mode in which a large amount of negative ions are generated compared to a positive ion, a mode in which a large amount of positive ions are generated compared to a negative ion, and a ratio of both positive and negative ions at about the same amount. The mode to generate | occur | produce can be switched.

2 is a circuit diagram showing a refrigeration cycle of the air conditioner. In the outdoor unit (not shown) connected to the indoor unit 1 of the air conditioner, the compressor 62, the four-way exchange valve 63, the outdoor heat exchanger 64, the blower fan 65, and the stop mechanism 66 are provided. To be prepared. One end of the compressor 62 is connected to the outdoor heat exchanger 64 by the refrigerant pipe 67 via the four-way exchange valve 63. The outer end of the compressor 62 is connected to the indoor heat exchanger 9 via the four-way exchange valve 63 by the refrigerant pipe 67. The outdoor heat exchanger 64 and the indoor heat exchanger 9 are connected via a stop mechanism 66 by a refrigerant pipe 67.

When the cooling operation starts, the compressor 62 is driven and the blowing fan 7 rotates. This allows the refrigerant to return to the compressor 62 via the compressor 62, the four-way switching valve 63, the outdoor heat exchanger 64, the stop mechanism 66, the indoor heat exchanger 9 and the four-way switching valve 63. Refrigeration cycle 680 is formed

When cooling by the operation of the refrigeration cycle 68, the indoor heat exchanger (9) is cooled to a temperature lower than the ambient temperature. In the heating operation, the four-way switching valve 63 is changed to rotate the blower fan 65, and the refrigerant flows in the reverse direction as described above. That is, refrigeration which returns to the compressor 62 via the compressor 62, the four-way switching valve 63, the indoor heat exchanger 9, the stop mechanism 66, the outdoor heat exchanger 64, and the four-way switching valve 63. The cycle 68 is formed. As a result, the indoor heat exchanger 9 is heated to a higher temperature than the ambient temperature.

3 is a block diagram showing the configuration of an air conditioner. The control part 60 is comprised by the microcomputer, and the blower fan 7, the compressor 62, the blower fan 65, according to the operation by a user, and the input of the temperature sensor 61 which detects the temperature of intake air, Drive control of the longitudinal louver 12, the wind direction variable parts 113a, 113b, 113c, and the ion generating device 30 is performed.

FIG. Is a block diagram showing the detailed configuration of the control unit 60. As shown in FIG. The control unit 60 has a CPU 71 that performs various calculation processes, and an input circuit 72 that receives an input signal and an output circuit 73 that outputs an operation result of the CPU 71 are connected to the CPU 71. It is. In addition, a memory 74 for storing arithmetic programs of the CPU 71 and temporarily storing arithmetic results is provided.

The output of the temperature sensor 61 is input to the input circuit 72. The output circuit 73 is connected with a drive motor (not shown) which drives the rotational shafts 113d, 113e, and 113f (see Fig. 1) of the wind direction variable portions 113a, 113b, and 113c.

In addition, an output of a light receiving unit (not shown) that receives an operation signal of a remote controller (not shown) is input to the control unit 60. Thereby, the wind direction variable parts 113a, 113b, and 113c can be driven without being bound by the detection result of the temperature sensor 61 by predetermined operation by a remote controller. That is, the direction control unit 113a, 113b, 113c can be arranged in any direction by prohibiting the control of the control unit 60 based on the temperature sensor 61.

In the air conditioner of the above configuration, when the heating operation is started, the refrigeration cycle is driven and the blower fan 65 of the outdoor unit (not shown) is rotationally driven. As a result, outside air is absorbed into the outdoor unit (not shown). The refrigerant absorbed by the outdoor heat exchanger 64 flows to the indoor heat exchanger 9 to heat the indoor heat exchanger 9.

When a predetermined time elapses from the start of the heating operation or when the indoor heat exchanger 9 is heated to a predetermined temperature, the blower fan 7 of the indoor unit 1 is rotationally driven by the control unit 60, and the first airflow Control is performed. As a result, air is absorbed from the suction port 4 into the indoor unit 1, and dust contained in the air is removed by the air filter 8. The air trapped in the indoor unit 1 is heated by heat exchange with the indoor heat exchanger 9, and is controlled by the longitudinal louver 12 and the wind direction varying units 113a, 113b, and 113c to regulate the directions in the left and right directions and the vertical direction. Send it out.

In the first airflow control, the wind direction variable parts 113a, 113b, and 113c are arranged in the state of FIG. 5 or FIG. 6, for example, to send the rough air in the front upward or approximately horizontal direction at a wind speed of about 3 to 4 m / sec. That is, as shown in FIG. 5, the wind direction variable part 113a is arrange | positioned toward the rear upward according to the airflow which flows through the front guide part 6a. The wind direction variable part 113b is substantially parallel to the airflow which distributes the front guide part 6a, and it arrange | positions it convexly by dividing the airflow into 2 parts. The wind direction variable part 113c is arrange | positioned under the cabinet 2, evacuating from the airflow sent out from the blower outlet 5. As shown in FIG.

Thereby, the rough air which flows through the front guide part 6a is bent, and is sent out from the blower outlet 5 to the front upward direction as shown by the arrow E. FIG. In addition, as shown in FIG. 6, by making the direction of the wind direction variable part 113a horizontal, the rough air is discharged | emitted from the blower outlet 5 in substantially horizontal direction, as shown by arrow D. As shown in FIG.

Harmonic air blown out from the blower outlet 5 in the front upward or substantially horizontal direction reaches the ceiling of the living room. Then, the wall surface W2 (refer FIG. 8), the floor surface F (refer FIG. 8) which opposes the indoor unit 1 from the ceiling wall S, and the wall surface Wl of the indoor unit 1 side are distributed sequentially by a Coanda effect. . Therefore, by the 1st airflow control, the conditioning air which is not heated up sufficiently at the time of starting operation of a heating operation does not directly contact a user, and can prevent a user from feeling a cold.

When a certain time has elapsed after the start of the heating operation or when the indoor heat exchanger 9 is sufficiently heated, the second air flow control is performed by the control unit 60. In the second air flow control, as shown in FIG. 1 described above, the wind direction variable parts 113a, 113b, and 113c are disposed, and the rough air is sent out from the outlet 5 at a rearward downward direction, for example, at a wind speed of about 6 to 7 m / sec. do.

That is, the wind direction variable part 113a is arrange | positioned in the position which extends to the upper side of the ventilation path 6 by the one end contacting the upper side of the plane side by the drive of a drive motor, and contacting the upper wall of the ventilation path 6. The outer end of the wind direction variable portion 113a is disposed downward to contact the rotation shaft 113e. The wind direction variable part 113b is arrange | positioned with the tip toward the rear downward so that the air flow path 6 side may become concave. The wind direction variable part 113c arrange | positions a tip toward rear downward so that the air flow path 6 side may be convex.

Thereby, the advancing direction front of the airflow which flows through the front guide part 6a is closed by the wind direction variable parts 113a and 113b, and the airflow is bent and guided to the rear downward. 7 shows the static pressure distribution of the blowing path 6 at this time. On the inner side of the wind direction variable parts 113a and 113b, the fixed pressure part 90 having a higher pressure than the static pressure of the front guide part 6a is formed in contact with the wind direction variable parts 113a and 113b.

According to the detection result of the positive pressure detection sensor (not shown) which detects the static pressure of the ventilation path 6, the wind direction variable parts 113a, 113b, and 113c are adjusted, and the isobar of the fixed pressure part 90 is variable in wind direction. It is formed along the airflow which flows toward the parts 113a and 113b. That is, the isobar 90a of the fixed pressure part 90 is formed in substantially parallel to the line connecting the end of the front guide part 6a and the end of the wind direction variable part 113b, and the airflow is near the fixed pressure part 90. It is substantially parallel to 90a.

For this reason, the high pressure part 90 acts as a hydrodynamic wall surface, and the direction of airflow of the rough air is smoothly changed by the wind direction varying parts 113a, 113b, and 113c to bend the airflow. The isobars 90a of the fixed pressure section 90 in contact with the wind direction varying sections 113a and 113b do not intersect with the streamline of the mainstream of the airflow that curves and distributes the blowing path 6. For this reason, the pressure loss related to airflow can be significantly reduced.

As a result, in spite of the change of a large wind direction, the rough air of a large wind volume can be sent backward and downward. In addition, in the fixed pressure section 90, a low speed and low energy airflow split from the mainstream flows along the wind direction variable sections 113a and 113b. For this reason, the influence on a pressure loss becomes small.

In addition, the arrangement of the wind direction variable parts 113a, 113b and 113c is varied so that the static pressure in the vicinity of the wind direction variable parts 113a and 113b becomes a predetermined value by using the positive pressure detection sensor, and the wind direction variable parts 113a and 113b, The position of 113c) may be stored as a database. As a result, the wind direction variable parts 113a, 113b, and 113c can be arranged at predetermined positions by taking data from the database according to the driving conditions, and the positive pressure detection sensor can be omitted.

Moreover, the mainstream of the rough air which flows toward the wind direction variable parts 113a, 113b, and 113c distributes the space enclosed by the fixed pressure part 90 and the lower wall surface of the blowing path 6. That is, the wall surface of the flow path is formed by the fixed pressure portion 90. Therefore, the airflow is not in contact with the wind direction varying portions 113a and 113b, so that the loss due to viscosity is reduced, and the amount of airflow can be further increased.

Moreover, the fixed pressure part 90 forms the wall surface of a flow path, the fixed pressure part 90 narrows the flow path of rough air, and forms a nozzle shape, and a flow path area becomes narrower than the front guide part 6a. For this reason, the fluid of high energy is sent out from the blower outlet 5 by the action of a nozzle. As a result, the wind speed of the airflow adjacent to the fixed pressure part 90 does not change significantly, and the static pressure fluctuation of the airflow is suppressed, and the airflow flows more smoothly, thereby reducing the pressure loss. Therefore, the air volume of the roughened air sent out from the air conditioner can be further increased.

Moreover, the flow path area narrowed by the fixed pressure part 90 and whose one end was narrowed is extended once again to the downstream side of the wind direction variable parts 113a, 113b, and 113c. As a result, the cross section decreases once in the flow path toward the downstream, so that a minimum cross-sectional area (hereinafter, referred to as a throat part) is formed. For this reason, what is called a diffuser is comprised by the enlarged flow path, and it can support the increase of the static pressure of the blowing fan 7, and can further increase the amount of wind. As shown in Fig. 7, since the fixed pressure portion 90 does not occur in the throat portion of the flow path and no pressure loss occurs, the curved portion without pressure loss can be formed by bending the flow path at the position. .

In addition, since the contact portion between the upper wall of the front guide portion 6a and the wind direction variable portion 113a is not formed by the smooth curved surface, the edge 25 is generated in the fixed pressure portion 90, and the blowing efficiency is slightly reduced. However, it is possible to suppress the increase in pressure loss compared to the prior art and improve the blowing efficiency.

Moreover, the wind direction variable part 113b is arrange | positioned so that the lower wall of the front guide part 6a may extend to the outer side of the blowout outlet 5, and intersect with the virtual surface 98. FIG. Thereby, the lower end of the wind direction variable part 113a is arrange | positioned below the virtual surface 98, and airflow is reliably guide | induced to the rear downward. Therefore, airflow is not sent out in an undesirable direction, and a highly reliable air conditioner can be obtained.

8 shows the behavior of the airflow in the living room R at the time of taking out the rear lower part. The roughened air descends along the sidewall Wl and returns to the inlet 4 by sequentially turning the floor surface F, the sidewall W2 facing the sidewall Wl, and the ceiling wall as indicated by arrow C. FIG. As a result, it is possible to prevent the warming up of the sent-out warm-up, to prevent a decrease in the heating efficiency due to the short circuit, and to sufficiently improve the comfort of the lower part of the living room R. Therefore, the room temperature rises quickly in the living room R, and it starts up.

In the first air flow control, when the air sent from the indoor unit 1 is directly treated, the temperature is so low that the user feels cold. For this reason, although room temperature rises also when 1st air flow control is performed, the rate of rise is slow. In the start-up state, even when the air sent from the indoor unit 1 directly touches, the temperature reaches the temperature at which the user does not feel cold, and the temperature rises quickly in a state where the room temperature is lower than the set temperature.

9 shows the temperature distribution in the room during the second air flow control. The set temperature of the room temperature is 28 ° C., and the size of the living room R is 6 tatami (2400 mm high, 3600 mm wide, 2400 mm deep). As described above with reference to FIGS. 30 and 31, the measurement point measures a total of 48 points of 6 points and 8 points in the height direction and the transverse direction, respectively, at 600 mm intervals at the center cross section of the living room R indicated by the dashed-dotted line D.

As shown in the figure, the conditioner air having a high temperature reaches the foot on the floor F, so that the temperature of the bottom surface center of the living room R is 33 ° C to 35 ° C. In the above-described conventional example shown in Figs. 30 and 31, the temperature is about 31 ° C to 32 ° C (Fig. 30) and 23 ° C (Fig. 31) at the same position, so that the temperature of the foot is higher to reduce the user's discomfort and comfort It is possible to improve significantly.

In addition, since the harmonic air sent out from the indoor unit 1 follows the wall surface by the Coanda effect, no winding is generated and a short circuit is not generated. For this reason, the warming-up pool E (refer FIG. 30) which becomes excessively warm around the indoor unit 1 does not generate | occur | produce, and the temperature of the intake port 4 vicinity is about the same as 28 degreeC which is set temperature. Therefore, while improving the air conditioning efficiency, it is possible to easily determine whether the room is sufficiently warm.

Next, when the fixed air flow is further controlled by the second air flow control, or when the temperature sensor 61 detects that the temperature difference between the temperature of the air blown in from the suction port 4 and the set temperature is small, The third air flow control is performed by the control unit 60. In the third air flow control, the driving frequency of the compressor 62 is lowered, and the wind direction variable parts 113a, 113b, and 113c are arranged as shown in Fig. 10, for example, an arrow C 'at a wind speed of about 6 to 7 m / sec. As shown by, rough air is sent to the rear downward.

That is, the wind direction variable part 113c is rotated in the K direction of FIG. 10 to narrow the area of the blowout port 5, and at the same time, the rotation speed of the blower fan 7 is adjusted to maintain the wind speed. As a result, the air volume gradually decreases to about 70% at the same wind speed as for the second air flow control. At this time, even if the airflow amount decreases, the rough air (warm-up) sent from the indoor unit 1 to the rear downwards does not wind up due to the Coanda effect and continues to descend along the side wall Wl, and does not flow directly into the living space. Rather than reach the feet on the floor F.

Therefore, there is no unpleasant feeling caused by direct wind on the user, and comfort is improved. In addition, since the wind speed is maintained even when the airflow amount decreases, warmth reliably reaches every corner of the living room R such as a boundary region between the side wall W2 and the bottom surface F. FIG. As a result, in the living room R, the room temperature is in a stable state in which the room temperature is stabilized within a predetermined temperature.

In addition, in the third airflow control, when the air volume is lowered and the wind speed is lowered, warm air may not reach all corners of the living room R such as the boundary area between the side wall W2 and the bottom surface F, so that the wind speed is maintained. It is more preferable to do.

If the room temperature of the living room R drops below the set temperature due to the opening of the window of the living room R, the interruption of the heating operation due to the defrost of the outdoor unit during the third airflow control, or for other reasons, the air conditioner shifts to the start-up state and the second Control the airflow. And when a fixed time passes or when it detects that the temperature difference between room temperature and a set temperature has become small, 3rd airflow control is performed. This operation is repeated to perform heating operation.

In addition, the user may wish to directly overwrite the warming up immediately after the start of heating operation or when the room temperature of the living room R does not reach a desired temperature. In addition, after the room temperature of the living room R reaches a desired temperature, it may be unpleasant to feel the unpleasant feeling of turning the egg directly upside down, so that there is a case where it is desired to maintain the room temperature at the desired temperature without directly inverting the egg temperature.

In such a case, as shown in the conventional example of Fig. 28 described above, the roughened air may be discharged forward and downward, and then discharged downward as shown in Figs. That is, in the start-up state, as shown in Fig. 28, the rough air is sent forward and downward. This makes it possible to spread the egg directly to the user. Then, in a stable state, the conditioner air is discharged backwards and downwards. This allows the user to maintain the temperature of the room at a desired temperature without inverting the warmth directly. Thus, the user's convenience can be greatly improved. have.

In addition, the arrangement of the longitudinal louver 12 and the wind direction variable parts 113a, 113b, and 113c can be changed by an operation of a remote controller (not shown) by a user. As a result, the wind direction of the conditioner air can be arbitrarily selected by the user.

In the second air flow control, as shown in FIG. 11 instead of the above-described state of FIG. 1, the plane side of the wind direction variable portion 113a may be arranged toward the blowing path 6. Thereby, the wind direction variable parts 113a and 113b are arrange | positioned along the front panel 3, and the aesthetics of the indoor unit 1 are improved. At this time, since the fixed pressure part 90 is formed surrounded by the upper wall of the blowing path 6 inclined upward and the wind direction variable parts 113a and 113b, the eddy 25 which develops in the fixed pressure part 90 becomes large. .

For this reason, although blowing efficiency falls slightly compared with the case of FIG. 1, the increase of a pressure loss can be suppressed compared with the former. Similarly, in the third air flow control, the wind direction variable portion 113a may be disposed along the front panel 3 instead of the state of FIG. 10 described above.

In the second and third air flow control, when the living room R in which the indoor unit 1 is installed is large, another control is performed by the control unit 60. Control switching can be performed by a switch etc. provided in the indoor unit 1 or a remote controller.

When the living room R is large and the distance between the side wall Wl where the indoor unit 1 is installed and the side wall W2 opposite the side wall Wl is relatively large, the boundary area between the side wall W2 and the bottom surface F when the rough air is blown out from the blower outlet 5 rearward and downward. Warming may not reach every corner of living room R of the back. For this reason, in the 2nd air flow control of a startup state, the wind direction variable part 113a, 113b, 113c is arrange | positioned as shown in FIG.

That is, the wind direction varying portions 113b and 113c are disposed forward than the state of FIG. 1 described above. And as shown by the arrow B, rough air is blown out from the blower outlet 5 at the wind speed about 7-8 m / sec, for example in substantially downward direction.

In the steady state, in the third air flow control, the wind direction variable portions 113a, 113b, and 113c are arranged as shown in FIG. That is, the area of the blowout outlet 5 can be narrowed by rotating the wind direction variable part 113c to the K direction from the state of FIG. Accompanying this, the rotation speed of the blowing fan 7 is adjusted. As a result, for example, the amount of air flow becomes about 70% of the second air flow control, and the roughened air is sent out in the direction substantially downward as indicated by the arrow B 'from the blowout port 5 at the wind speed of about 7 to 8 m / sec. do. This makes it possible to reach warm air in every corner of the living room R when the living room R is large.

Further, in the second and third air flow control, as shown in Figs. 14 and 15, the wind direction variable portions 113a, 113b and 113c may be disposed, respectively. That is, in the second air flow control in the start-up state, the lower ends of the wind direction variable parts 113a, 113b, and 113c are disposed forward in comparison with FIG. 12 in FIG. Then, as shown by arrow A2, for example, at a wind speed of about 6 to 7 m / sec from the air outlet 5, the roughened air is discharged slightly forward and downward rather than immediately below.

In the third air flow control in the stable state, the wind direction variable portion 113a rotates in the forward direction from the state of FIG. 14 in FIG. 15, the wind direction variable portion 113c rotates in the K direction, and the area of the outlet 5 is narrow. Can lose. Accompanying this, the rotation speed of the blowing fan 7 is adjusted. As a result, for example, the amount of air flow becomes about 70% of the second air flow control, and the roughened air is sent from the blowout port 5 to the front downward as shown by the arrow A2 'at the wind speed of about 7 to 8 m / sec. Thereby, when the living room R is large, warm air can reach all corners of the living room R.

In the second and third air flow control, the wind direction variable parts 113a, 113b, and 113c may be arranged as shown in Figs. 1 and 10, respectively, to increase the wind speed. That is, in the start-up state, as shown in Fig. 1, the wind direction variable parts 113a, 113b, and 113c are set, and as shown by the arrow C from the outlet 5, for example, the wind speed is about 9 to 10 m / sec. To send out harmonic air.

In the stable state, as shown in Fig. 10, the wind direction variable parts 113a, 113b, and 113c are set, and as shown by an arrow C from the blowout port 5, the air flow is at a rearward downward direction, for example, at a wind speed of about 9 to 10 m / sec. Send the. Thereby, even if the living room R is large, warm air can reach all corners of the living room R. Therefore, when the living room R is large, the same effect as when the living room is narrow can be obtained by setting the wind direction forward or increasing the wind speed.

Second Embodiment

Next, Fig. 16 is a side sectional view showing the indoor unit 1 of the air conditioner of the second embodiment. The same reference numerals are attached to the same parts as those in the first embodiment shown in Figs. In the present embodiment, the wind direction variable parts 114a and 114b are installed instead of the wind direction variable parts 113a, 113b and 113c of the first embodiment. Other parts are the same as in the first embodiment.

The wind direction variable parts 114a and 114b are arranged in the air outlet 5, and both surfaces are comprised by the flat plate. The rotation shafts 114c and 114d rotatably support the wind direction variable portions 114a and 114b and rotate by a drive motor (not shown). Thereby, the wind direction variable parts 114a and 114b are comprised by the wind direction plate which changes a direction by the drive of a drive motor, and changes a wind direction. In addition, the rotation shaft 114c is provided at approximately the center of the wind direction variable part 114a, and the rotation shaft 114d is provided at the end of the wind direction variable part 114b. In addition, the figure has shown the arrangement | positioning at the time of sending a roughened air backward and downward.

In the air conditioner of the above configuration, when the heating operation is started, the refrigeration cycle is driven and the blower fan 65 of the outdoor unit (not shown) is rotationally driven. As a result, outside air is absorbed into the outdoor unit (not shown). The refrigerant absorbed by the outdoor heat exchanger 64 flows to the indoor heat exchanger 9 to heat the indoor heat exchanger 9.

When a predetermined time elapses from the start of the heating operation, or when the indoor heat exchanger 9 is heated to a predetermined temperature, the blowing fan 7 of the indoor unit 1 is rotationally driven by the control unit 60, and the first Airflow control is performed. As a result, air is sucked into the indoor unit 1 from the intake port 4, and dust contained in the air is removed by the air filter 8. The air blown into the indoor unit 1 is the indoor heat exchanger 9. Is heated by heat exchange with the longitudinal louver 12 and the wind direction changing parts 114a and 114b to control the direction in the left and right direction and the up and down direction, and is sent out to the room.

In the first air flow control, the wind direction variable parts 114a and 114b are arranged in the state shown in Fig. 17 or 18, and the rough air is sent out in the front upward or approximately horizontal direction at a wind speed of about 3 to 4 m / sec. That is, as shown in FIG. 17, the front end of the wind direction variable part 114a is arrange | positioned upwards rather than a rear end, and is substantially parallel to the upper wall of the ventilation path 6 inclined upwards in the vicinity of the blower outlet 5. As shown in FIG. The wind direction variable part 114b is arrange | positioned so that the edge part of an axial side may become lower than the edge part of an open side.

Thereby, the rough air which flows through the front guide part 6a is bent, and is sent out from the blower outlet 5 to the front upward direction as shown by the arrow E. FIG. 18, if the direction of the wind direction variable part 114a is made horizontal, as shown by arrow D, rough air will be sent out from the blower outlet 5 in substantially horizontal direction.

Harmonic air blown out from the blower outlet 5 in the front upward or substantially horizontal direction reaches the ceiling of the living room. Subsequently, by the Coanda effect, it flows through the wall surface W2 (refer FIG. 8), the floor surface F (refer FIG. 8) which opposes the indoor unit 1 from the ceiling surface, and the wall surface Wl on the indoor unit 1 side sequentially. Therefore, the first air flow control prevents the user from feeling cold because the conditioner air that is not sufficiently heated at the start of heating operation is not directly treated by the user.

When a predetermined time has elapsed after the start of the heating operation or when the indoor heat exchanger 9 is sufficiently heated, the second air flow control is performed by the control unit 60. In the second airflow control, as shown in FIG. 16 described above, the wind direction variable parts 114a and 114b are arranged, and the rough air is sent out from the outlet 5 at the rear, for example, at a wind speed of about 6 to 7 m / sec. .

That is, the wind direction variable part 114a is arrange | positioned so that one end may extend downward along an upper wall near the upper wall of the blowing path 6 by drive of a drive motor. The outer end of the wind direction variable portion 114a is disposed downward toward the rotation shaft 114d. The wind direction variable part 114b is arrange | positioned with the front end downward.

Thereby, the advancing direction front of the airflow which distributes the front guide part 6a is closed by the wind direction variable parts 114a and 114b, and the fixed pressure part 90 which contacts the wind direction variable parts 114a and 114b is formed. The isobars 90a (see Fig. 7) of the fixed pressure section 90 are formed along the flow direction of the conditioner air toward the wind direction variable sections 114a and 114b as in the first embodiment. For this reason, the fixed pressure part 90 becomes a hydrodynamic wall surface, and rough air changes smoothly in a delivery direction, and it is sent to the back downward from the blowout port 5. As shown in FIG.

Therefore, as in the first embodiment, it is possible to reduce the discomfort of the user and to greatly improve the comfort by making the temperature of the foot higher in the startup state. In addition, the air conditioning efficiency is improved, and it becomes possible to easily determine whether the room is sufficiently warm.

Moreover, the flow path can be narrowed by the fixed pressure part 90, and the flow path is extended once again downstream. In addition, the wind direction variable part 114b is arrange | positioned so that the lower wall of the front guide part 6a may cross | intersect the imaginary surface 98 which extends outward from the blowout opening 5. Therefore, the same effect as in the first embodiment can be obtained.

Next, when a certain time has elapsed after the start of the heating operation, or when the temperature sensor 61 detects that the temperature difference between the temperature of the air blown in from the suction port 4 and the set temperature is small, the controller By 60, the third air flow control is performed. In the third air flow control, as shown in Fig. 19, the wind direction variable parts 114a and 114b are disposed, and the air flow rate of the tunic fan 7 is lowered to substantially lower the direction as indicated by the arrow B at a wind speed of about 5 to 6 m / sec. Harmonious air is sent out.

That is, the wind direction variable part 114b arranges the front end more than the case of FIG. 16, and points it to the substantially downward direction, and the air volume and the wind speed fall. Thereby, there is no unpleasant feeling by the wind which a user directly encounters in a stable state, and comfort improves. Moreover, even if the airflow amount decreases, since the roughened air is sent slightly forward (approximately just below) from the indoor unit 1 to the start-up state, warm air reaches a position away from the indoor unit 1. Furthermore, in the first embodiment, the air flow path can be narrowed in the third air flow control in the stable state to maintain the wind speed, thereby reducing the airflow amount, which is more preferable.

If the room temperature of the living room R drops below the set temperature due to the opening of the window of the living room R during the third airflow control, the suspension of the heating operation due to the defrost of the outdoor unit, or for other reasons, the air conditioner shifts to the room temperature start-up state and the second To control the airflow. Then, the third air flow control is performed when a predetermined time has elapsed or when the temperature difference between the room temperature and the set temperature is reduced. This operation is repeated to perform heating operation.

Moreover, the arrangement | positioning of the longitudinal louver 12 and the wind direction variable parts 114a and 114b can be changed by operation of a remote controller (not shown) by a user. As a result, the wind direction of the conditioner air can be arbitrarily selected by the user.

In the second airflow control, as shown in FIG. 20 instead of the above-described state of FIG. 16, the wind direction variable portion 114a may be disposed along the front panel 3. This improves the aesthetics of the indoor unit 1. At this time, since the fixed pressure part 90 is formed by being surrounded by the upper wall of the blowing path 6 and the wind direction variable parts 114a and 114b which are inclined forward, the eddy 25 which develops in the fixed pressure part 90 is large. do.

For this reason, although blowing efficiency falls slightly compared with the case of FIG. 16, the increase of a pressure loss can be suppressed compared with the former. Similarly, in the third air flow control, the wind direction variable part 114a may be disposed along the front panel 3 instead of the above-described state of FIG.

In the second and third air flow control, when the living room R in which the indoor unit 1 is installed is large, another control is performed by the control unit 60. Control switching can be performed by a switch etc. provided in the indoor unit 1 or a remote controller.

If the living room R is wide and the distance between the side wall Wl where the indoor unit 1 is installed and the side wall W2 opposite the side wall W1 is relatively large, the boundary between the side wall W2 and the bottom surface F is to be discharged from the blower outlet 5 to the rear side. Warming may not reach every corner of living room R, such as an area | region. For this reason, in the 2nd air flow control of a startup state, the wind direction variable part 114a, 114b is arrange | positioned as shown in FIG. 19 mentioned above.

That is, the wind direction variable part 114b is disposed forward than the state of FIG. Then, as shown by arrow B, for example, at a wind speed of about 7 to 8 m / sec, the roughened air is blown out from the outlet 5 in the direction immediately below.

In the steady state, in the third air flow control, the wind direction variable portions 114a and 114b are arranged as shown in FIG. That is, the wind direction variable part 114b0 is arrange | positioned ahead of the state of FIG. 19 mentioned above, and, as shown by the arrow B with the wind speed of about 6-7 m / sec, for example, from the blower outlet 5, rather than just underneath. Slightly forward and downward, so that warm air can reach the corner of living room R even if living room R is wide.

Third Embodiment

Next, Fig. 22 is a side sectional view showing the indoor unit 1 of the air conditioner of the third embodiment. The same reference numerals are attached to the same parts as those in the second embodiment shown in Figs. In this embodiment, instead of the wind direction variable portions 114a and 114b of the second embodiment, the wind direction variable portions 115a and 115b are provided.

In addition, a rotation speed detection unit (not shown) is provided which detects the rotation speed of the blower fan 7 in the indoor unit 1 and detects the amount of airflow of the conditioner air discharged from the blowout port 5. The output of the rotation speed detection unit is input to the control unit 60, and the wind direction variable units 115a and 115b are driven based on the detection result of the rotation speed detection unit. Other parts are the same as in the second embodiment.

The wind direction variable parts 115a and 115b are arranged in the air outlet 5, and both surfaces are comprised by the flat plate. The rotation shafts 115c and 115d rotatably support the wind direction variable portions 115a and 115b and rotate by a drive motor (not shown). Thereby, the wind direction variable parts 115a and 115b are comprised by the wind direction plate which changes a direction by the drive of a drive motor, and changes a wind direction. In addition, the rotation shaft 115c is provided at a substantially center of the wind direction variable part 115a, and the rotation shaft 115d is installed at a position separated by a predetermined amount from the wind direction variable part 115b which is approximately the center of the wind direction variable part 115b. do. Moreover, the figure has shown the arrangement | positioning at the time of sending roughened air backward and downward.

In the air conditioner of the above configuration, when the heating operation is started, the refrigeration cycle is driven and the blower fan 65 of the outdoor unit (not shown) is rotationally driven. As a result, outside air is absorbed into the outdoor unit (not shown). The refrigerant absorbed by the outdoor heat exchanger 64 flows to the indoor heat exchanger 9 to heat the indoor heat exchanger 9.

When a predetermined time elapses from the start of the heating operation, or when the indoor heat exchanger 9 is heated to a predetermined temperature, the blowing fan 7 of the indoor unit 1 is rotationally driven by the control unit 60, and the first Airflow control is performed. As a result, air is sucked into the indoor unit 1 from the intake port 4, and dust contained in the air is removed by the air filter 8. The air blown into the indoor unit 1 is heated by heat exchange with the indoor heat exchanger 9, and is controlled by the longitudinal louvers 12 and the wind direction variable parts 115a and 115b to control the directions in the left and right directions and the vertical direction. It is sent out.

In the first air flow control, the wind speed varying parts 115a and 115b are arranged in the state shown in Fig. 23 or 24 by detecting the rotation speed detection unit with the rotation speed of the blowing fan 7 being 600 rpm, for example. Harmonic air is sent out in the forward or approximately horizontal direction at a wind speed of about 3 to 4 m / sec. That is, as shown in FIG. 23, the wind direction variable part 115a is arrange | positioned above the rear end, and is substantially parallel to the upper wall of the ventilation path 6 inclined upward from the ejection opening 5 vicinity. The wind direction variable part 115b is arrange | positioned so that the outer edge part may become lower than the inner edge part.

Thereby, the rough air which flows through the front guide part 6a is bent, and is sent out from the blower outlet 5 to the front upward direction as shown by arrow E. FIG. In addition, as shown in FIG. 24, when the direction of the wind direction variable part 115a is made horizontal, as shown by arrow D, a rough air will be sent out from the blower outlet 5 in substantially horizontal direction.

Harmonic air blown out from the blower outlet 5 in the front upward or substantially horizontal direction reaches the ceiling of the living room. Then, the wall surface W2 (refer FIG. 8), the floor surface F (refer FIG. 8) which opposes the indoor unit 1 from the ceiling surface, and the wall surface Wl of the indoor unit 1 side are distributed in turn by the Coanda effect. Accordingly, the first air flow control prevents the user from feeling cold because the conditioner air that is not sufficiently heated at the start of heating operation does not face the user directly.

When a predetermined time has elapsed after the start of the heating operation or when the indoor heat exchanger 9 is sufficiently heated, the second air flow control is performed by the control unit 60. In the second air flow control, the wind direction variable parts 115a and 115b are arranged in the above-described state of Fig. 22 by detecting the rotation speed detection unit at a rotation speed of, for example, 1200 rpm. And the rough air is sent to the rear downward at the wind speed of about 6-7 m / sec.

That is, the wind direction variable part 115a is arrange | positioned so that one end may abut on the upper wall of the ventilation path 6 by the drive motor, and may extend below the upper wall. The wind direction variable part 115b is arrange | positioned so that the front end may be substantially directly downward or rearward downward.

Thereby, the advancing direction front of the airflow which distributes the front guide part 6a is closed by the wind direction variable parts 115a and 115b, and the fixed pressure part 90 which faces the wind direction variable parts 115a and 115b is formed. The isobars 90a (see Fig. 7) of the fixed pressure section 90 are formed along the flow direction of the conditioner air toward the wind direction varying sections 115a and 115b as in the first and second embodiments. For this reason, the fixed-pressure part 90 becomes a hydrodynamic wall surface, and rough air changes smoothly in a delivery direction, and it is sent to the back downward from the blowout port 5. As shown in FIG.

Therefore, as in the first and second embodiments, it is possible to reduce the discomfort of the user and to greatly improve the comfort by making the temperature of the step higher in the startup state. In addition, the air conditioning efficiency is improved, and it is possible to facilitate the determination of whether the room is sufficiently warm.

Moreover, the flow path can be narrowed by the fixed pressure part 90, and the flow path has once again expanded downstream. In addition, the wind direction variable part 115b is arrange | positioned so that the lower wall of the front guide part 6a may cross | intersect the imaginary surface 98 which extends outward from the blower outlet 5. Therefore, the same effects as in the first and second embodiments can be obtained.

Next, when a certain time has elapsed after the start of the heating operation, or when the temperature sensor 61 detects that the temperature difference between the temperature of the air blown in from the suction port 4 and the set temperature is small, the controller By 60, the third air flow control is performed. In the third air flow control, the wind speed varying portions 115a and 115b are arranged in the state shown in Fig. 25 by detecting the rotation speed detection unit at a rotation speed of, for example, 900 rpm. And rough air is sent out in substantially downward direction as shown by arrow B at a wind speed of about 5-6 m / sec.

That is, as the number of revolutions of the blowing fan 7 is lowered, the wind direction variable part 115b can arrange the tip forward than in the case of Fig. 22 so that the tip is directed directly under or slightly forward. As a result, there is no discomfort caused by the wind directly facing the user in a stable state, and comfort is improved. Moreover, even if the airflow amount decreases, since the roughened air is sent out slightly from the indoor unit 1 to the start state (approximately just below) from the startup state, the warm-up reaches the position away from the indoor unit 1.

If the room temperature of the living room R drops below the set temperature due to the opening of the window of the living room R during the third airflow control, the heating operation is suspended due to the defrost of the outdoor unit, or for other reasons, the air conditioner enters the room temperature startup state and the second airflow Take control. And when a fixed time passes or when it detects that the temperature difference between room temperature and a set temperature has become small, 3rd airflow control is performed. This operation is repeated to perform heating operation.

Moreover, the arrangement | positioning of the longitudinal louver 12 and the wind direction variable parts 115a and 115b can be changed by operation of a remote controller (not shown) by a user. As a result, the wind direction of the conditioner air can be arbitrarily selected by the user.

In the second and third air flow control, when the living room R provided with the indoor unit 1 is wide, another control is performed by the control unit 60. Control switching can be performed by an exchange switch or the like installed in the indoor unit 1 or a remote controller.

When the living room R is large and the distance between the side wall Wl where the indoor unit 1 is installed and the side wall W2 opposite the side wall W1 is relatively large, the boundary between the side wall W2 and the bottom surface F is discharged when the rough air is blown backward from the blowout port 5. Warming may not reach every corner of living room R, such as an area | region. For this reason, in the 2nd air flow control of a startup state, the wind direction variable part 115a, 115b is arrange | positioned as shown in FIG. 25 mentioned above.

That is, if the rotation speed of the blower fan 7 becomes 1200 rpm, for example, the wind direction variable part 115b is arrange | positioned ahead of the state of FIG. 22 mentioned above by detection of a rotation speed detection part. And, as shown by arrow B, for example, at a wind speed of about 7 to 8 m / sec from the blowout port 5, the roughened air is sent out in the direction of approximately immediately below.

In the steady state, in the third air flow control, the wind direction variable parts 115a and 115b are arranged as shown in FIG. That is, when the rotation speed of the blower fan 7 becomes 900 rpm, for example, the wind direction variable part 115b is arrange | positioned ahead of the state of FIG. 25 mentioned above by detection of a rotation speed detection part. As shown by arrow B, for example, at a wind speed of about 6 to 7 m / sec, the roughened air is discharged from the air outlet 5 to the front forward and downward rather than immediately below. Thereby, even if the living room R is large, warming can reach all corners of the living room R.

In addition, in the 1st, 2nd Example, the same rotation speed detection part may be provided and the wind direction, the wind speed, and the air volume may be changed based on the detection result of the rotation speed detection part.

Fourth Embodiment i

Next, a fourth embodiment will be described. In this embodiment, a frequency detector (not shown) is provided in place of the rotation speed detector for the air conditioner of the third embodiment. The frequency detector detects an operating frequency of the compressor 62 (see Fig. 2). In FIG. 4 described above, the output of the frequency detector is input to the controller 60, and the wind direction variable units 115a and 115b are driven based on the detection result of the frequency detector. Other parts are the same as in the third embodiment.

Thereby, arrangement | positioning of the wind direction variable parts 115a and 115b can be changed according to the operating frequency of the compressor 62. FIG. In the second air flow control in the start-up state, when the operating frequency is increased, and the operating frequency becomes 70 Hz or more, for example, the wind direction variable parts 115a and 115b are shown in FIG. 22 described above by detection of the frequency detector. Are placed in a state. Further, in the third air flow control in the stable state, when the driving frequency is lowered and the driving frequency becomes 40 Hz to 70 Hz, for example, the wind direction variable units 115a and 115b are detected by the frequency detector, for example. It is arranged in the state shown in 25.

At the time of heating, when the operation frequency of the compressor 62 is high, the heating capacity is improved, and the temperature of the indoor heat exchanger 9 is increased. When the operating frequency of the compressor 62 is low, the heating capacity is lowered and the temperature of the indoor heat exchanger 9 is lowered. Therefore, as mentioned above, a part of rough air which has a high blowout temperature is sent back more. As a result, the hot air facing the user can be reduced to further reduce the user's discomfort. Furthermore, in the first and second embodiments, a frequency detector may be provided.

Fifth Embodiment

Next, a fifth embodiment will be described. In the present embodiment, the blower path 6 is provided with a blowout temperature detector (not shown) composed of a temperature sensor for detecting the blowout temperature of the air conditioner instead of the rotation speed detector. 4, the output of the blowout temperature detector is input to the controller 60 instead of the output of the temperature sensor 61, and the wind direction variable units 115a and 115b are driven based on the detection result of the blowout temperature detector. It is becoming. Other parts are the same as in the third embodiment.

Thereby, the setting of the wind direction variable parts 115a and 115b can be changed according to the blowout temperature of the roughened air. When the temperature of the indoor heat exchanger does not rise and the extraction temperature is less than 36 ° C, the first air flow control is performed. In the second air flow control in the startup state, the blowout temperature rises due to an increase in the operating frequency of the compressor, and when the blowout temperature reaches 45 ° C or higher, the wind direction variable parts 115a and 115b are for example detected by detection of the blowout temperature detector. It is arranged in the state shown in Fig. 22 described above.

In the third air flow control in the stable state, when the operating frequency of the compressor 62 is decreased, and the blowout temperature reaches 36 ° C to 45 ° C, the wind direction variable parts 115a and 115b are described, for example, by the detection of the blowout temperature detector. It is arrange | positioned in the state shown in FIG. Therefore, as described above, part of the rough air having a high blowing temperature is further sent out to the rear. Thereby, the hot air facing a user can be reduced and the user's discomfort can be further reduced. Furthermore, in the first and second embodiments, the extraction temperature detector may be provided.

Sixth Example

Next, a sixth embodiment will be described. In the present embodiment, a heat exchanger temperature detector (not shown) that is constituted of a temperature sensor that detects the temperature of the indoor heat exchanger 9 is provided in place of the rotational speed detector in the air conditioner of the third embodiment. 4, the output of the heat exchanger temperature detector is input to the controller 60, and the wind direction variable units 115a and 115b are driven based on the detection result of the heat exchanger temperature detector. Other parts are the same as in the third embodiment.

Thereby, the setting of the wind direction variable parts 115a and 115b can be changed according to the temperature of the indoor heat exchanger 9. For example, when the temperature of the indoor heat exchanger 9 is less than 40 degreeC, 1st air flow control is performed. In the second air flow control in the startup state, the temperature of the indoor heat exchanger 9 increases due to an increase in the operating frequency of the compressor 62, and when the temperature reaches 50 ° C or higher, the wind direction variable part 115a is detected by the detection of the heat exchanger temperature detector. And 115b are disposed, for example, in the state shown in Fig. 22 described above.

In the third air flow control in the stable state, when the operating frequency of the compressor 62 is lowered and the temperature of the indoor heat exchanger 9 becomes from 40 ° C to 50 ° C, the wind direction variable part 115a, 115b) is disposed, for example, in the state shown in FIG. 25 described above. Therefore, as described above, part of the rough air having a high blowing temperature is further sent out to the rear. Thereby, the hot air facing a user can be reduced and the user's discomfort can be further reduced. Furthermore, in the first and second embodiments, a heat exchanger temperature detector may be provided.

Seventh Example

Next, a seventh embodiment will be described. In this embodiment, the consumption current detection unit is provided in place of the rotation speed detection unit for the air conditioner of the third embodiment. The current consumption detector is constituted by a current transformer or the like that generates a secondary voltage proportional to the current value, and detects the current consumption or power consumption during operation of the air conditioner. 4, the output of the current consumption detector is input to the controller 60, and the wind direction variable units 115a and 115b are driven based on the detection result of the current consumption detector. Other parts are the same as in the third embodiment.

Thereby, the setting of the wind direction variable parts 115a and 115b can be changed according to the consumption current of the air conditioner. In the second air flow control in the startup state, when the operating frequency of the compressor 62 increases, and the current consumption or power consumption of the air conditioner becomes, for example, 12 A or 1200 W or more, the wind direction variable part is detected by the detection of the current consumption detector. 115a and 115b are disposed, for example, in the state shown in FIG. 22 described above.

In the third air flow control in the steady state, when the operating frequency of the compressor 62 decreases, and the current consumption or power consumption of the air conditioner becomes, for example, 7A to 12A or 700W to 1200W, the wind direction is detected by the detection of the current consumption unit. The variable parts 115a and 115b are disposed in the state shown in Fig. 25 described above, for example.

It is considered that the frequency of the compressor 62 (see Fig. 2) is high when the current consumption or power consumption during operation of the air conditioner is large, and the temperature of the indoor heat exchanger 9 is increased during heating. It is considered that the operating frequency of the compressor 62 is low when the current consumption or power consumption during operation of the air conditioner is small, and the temperature of the indoor heat exchanger 9 is lowered during heating. Some of the higher harmonic air is sent out further back. As a result, the hot air facing the user can be reduced to further reduce the user's discomfort. Furthermore, in the first and second embodiments, the current consumption detector may be provided.

Eighth Embodiment

Next, an eighth embodiment will be described. In this embodiment, the outdoor unit rotation speed detection unit is provided in place of the rotation speed detection unit for the air conditioner of the third embodiment. The outdoor rotation speed detection unit detects the rotation speed of the blower fan 65 (refer to FIG. 2) provided in the outdoor unit, and detects the amount of air sucked from the intake port (not shown) of the outdoor unit. 4, the output of the outdoor rotation speed detection unit is input to the control unit 60, and the wind direction variable units 115a and 115b are driven based on the detection result of the outdoor rotation speed detection unit. Other parts are the same as in the third embodiment.

Thereby, the setting of the wind direction variable parts 115a and 115b can be changed according to the rotation speed of the outdoor blower fan 65. In the second air flow control, for example, when the rotation speed of the outdoor blowing fan 65 is 1000 rpm or more, the wind direction variable parts 115a and 115b are arranged in the state shown in Fig. 22 by the detection of the outdoor rotation speed detection unit. In the third air flow control, for example, when the rotation speed of the outdoor blowing fan 65 reaches 500 to 1000 rpm, the wind direction variable parts 115a and 115b are arranged in the state shown in Fig. 25 by the detection of the consumption current detection unit.

At the time of heating, when the operating frequency of the compressor 62 (refer to FIG. 2) is high, the air flow rate or rotational speed of the blower fan 65 of the outdoor unit is also set large, and the heating capacity is improved to increase the temperature of the indoor heat exchanger 9. . When the operating frequency of the compressor 62 is low, the air flow rate or rotational speed of the blower fan 65 of the outdoor unit is also set less, the heating capacity is lowered and the temperature of the indoor heat exchanger 9 is lowered.

Therefore, as described above, part of the rough air having a high blowing temperature is further sent out to the rear. This reduces the hot air facing the user and further reduces the user's discomfort. Furthermore, in the first and second embodiments, an outdoor rotation speed detection unit may be provided.

<Example 9>

Next, a ninth embodiment will be described. In this embodiment, a humidity sensor is provided in place of the rotation speed detection unit for the air conditioner of the third embodiment. The humidity sensor is installed between the indoor heat exchanger 9 and the air filter 8 to detect the humidity of the intake air. In FIG. 4 described above, the output of the humidity sensor is input to the control unit 60 instead of the output of the temperature sensor 61, and the wind direction variable units 115a and 115b are driven based on the detection result of the humidity sensor. Other parts are the same as in the third embodiment.

Thereby, it is possible to vary the setting of the wind direction variable parts 115a and 115b according to the humidity of the intake air. For example, when the difference between the relative humidity of the intake air and the set humidity is 20% or more, the second air flow control is performed. When the difference between the relative humidity of the intake air and the set humidity is less than 20%, third air flow control is performed.

Therefore, when the difference between the relative humidity of the intake air and the set humidity is large, the conditioner air can be sent further to the rear to greatly enlarge the air of the entire room, and the nonuniformity of humidity can be adjusted quickly in every corner of the room. On the other hand, when the difference between the relative humidity of the intake air and the set humidity is small, the air is discharged in the direction immediately below to reduce the unnecessary air to the rear, thereby efficiently performing air conditioning. Furthermore, in the first and second embodiments, a humidity sensor may be provided.

<Example 10>

Next, a tenth embodiment will be described. In this embodiment, an ion sensor (not shown) is provided in place of the rotation speed detection unit for the air conditioner of the third embodiment. The ion sensor is provided between the indoor heat exchanger 9 and the air filter 8 to detect the ion concentration of the intake air. 4, the output of the ion sensor is input to the control unit 60 instead of the output of the temperature sensor 61, and the wind direction variable parts 115a and 115b are driven based on the detection result of the ion sensor. Other parts are the same as in the third embodiment.

Thereby, the setting of the wind direction variable parts 115a and 115b can be changed according to the ion concentration of the intake air. For example, when the difference between the ion concentration of the intake air and the set ion concentration is 2000 / cm ³ or more, the second air flow control is performed. The difference between the ion concentration of the intake air and the set ion concentration is 2000 pieces / cm ³ If less, the third air flow control is performed.

Therefore, when the difference between the ion concentration of the intake air and the set ion concentration is large, the conditioner air containing a large amount of ions is further discharged to the rear to greatly enlarge the air in the entire room, and to quickly adjust the balance of ions to every corner of the room. have. On the other hand, when the difference between the ion concentration of the intake air and the set ion concentration is small, the air is discharged directly downward to reduce the unnecessary air discharge, thereby efficiently providing air conditioning. Furthermore, in the first and second embodiments, an ion sensor may be provided.

<Eleventh embodiment>

Next, an eleventh embodiment will be described. This embodiment is the air conditioner of the third embodiment

The dust sensor (purity detection means) is provided instead of the rotation speed detection part. The dust sensor is installed between the indoor heat exchanger 9 and the air filter 8, and detects the amount of dust in the intake air to detect the degree of purification of air in the room. In FIG. 4 described above, the output of the dust sensor is input to the control unit 60 instead of the output of the temperature sensor 61, and the wind direction variable units 115a and 115b are driven based on the detection result of the dust sensor. Other parts are the same as in the third embodiment.

Thereby, the installation of the wind direction variable parts 115a and 115b can be varied according to the amount of dust contained in the intake air. For example, when the amount of dust in the intake air is larger than the predetermined amount, the second air flow control is performed. When the amount of dust in the intake air is less than the predetermined amount, third air flow control is performed.

Therefore, when the amount of dust contained in the intake air is large, the rough air is sent further to the rear to greatly enlarge the air of the entire room, the indoor dust is blown into the indoor unit, and the air filter 8 promptly cleans the air. Therefore, the air of the whole room can be cleaned in a short time. On the other hand, when the amount of dust contained in the intake air is small, the air is discharged in the direction immediately downward, thereby reducing the unnecessary air flow to the rear, so that air conditioning can be performed efficiently. In addition, when an HEPA filter or an electrostatic precipitator is used instead of the air filter 8 (see FIG. 1), a larger air cleaning effect can be obtained. Furthermore, in the first and second embodiments, dust sensors may be provided.

<Twelfth Example>

Next, a twelfth embodiment will be described. This embodiment is the air conditioner of the third embodiment

For the machine, an odor sensor (purity detection means) is provided instead of the rotation speed detection unit. The malodor sensor is provided between the indoor heat exchanger 9 and the air filter 8, and detects the content of the malodorous component of the intake air to detect the degree of purification of the indoor air. 4, the output of the malodor sensor is input to the controller 60 instead of the output of the temperature sensor 61, and the wind direction variable parts 115a and 115b are driven based on the detection result of the malodor sensor. Other parts are the same as in the third embodiment.

Thereby, the setting of the wind direction variable parts 115a and 115b can be changed according to the content of the malodorous component in the intake air. For example, when there is more malodorous component of intake air than predetermined amount, 2nd airflow control is performed. When the malodorous component of the intake air is less than the predetermined amount, third air flow control is performed.

Therefore, in the case where the content of the malodorous component in the intake air is large, the rough air is sent further to the rear to greatly enlarge the air of the whole room, the dust in the room is blown into the indoor unit, and the air filter 8 promptly cleans the air. Since it can carry out, the air of the whole room can be cleaned in a short time. On the other hand, when the content of the malodorous component in the intake air is small, it is possible to send the air just downward and reduce the unnecessary air to the rear to efficiently perform air conditioning. Furthermore, in the first and second embodiments, a malodor sensor may be provided.

<Thirteenth Example>

This embodiment is constituted like a so-called corner air conditioner in which the indoor unit 1 of the first embodiment is installed at a position in contact with the ceiling wall S of the corner L where two adjacent sidewalls W3, W4 of the living room R intersect, as shown in FIG. do. Also in this case, the above effects can be obtained. Furthermore, the indoor unit of the second to twelfth embodiments may be a corner air conditioner.

As mentioned above, although the air conditioner which concerns on this invention was demonstrated by the 1st-13th Example, this invention is not limited to the said Example, Addition of a suitable change in the range which does not deviate from the meaning of this invention, It can be carried out.

According to the present invention, it can be used for an air conditioner that harmonizes the air blown into the cabinet and sends it out to the room.

Claims (66)

delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete Intake to accept air, Blowout outlets, A blowing path communicating with the intake port from the intake port, and In the air conditioner which is installed in the blowing path for sending air, and installed on the wall surface of the room to operate, A first wind direction variable part rotatably supported at an upper portion of the outlet; A second wind direction variable part rotatably supported at a lower part of the first wind direction variable part, An upper end of the first wind direction variable part is continuously disposed at an upper wall of the blowing path, and a second wind direction variable part is continuously disposed at a lower part of the first wind direction variable part. An air conditioner characterized by being able to extend by two wind direction variable parts. 34. The air conditioner according to claim 33, wherein a first wind direction variable portion and a second wind direction variable portion are arranged to extend an upper wall of the air blowing path when air is discharged directly downward, rearward downward or forward downward from the blowout port. The air conditioner according to claim 33, wherein an isobar of a constant pressure distribution in the vicinity of the first wind direction variable part and the second wind direction variable part is formed along a flow direction of air facing the first wind direction variable part and the second wind direction variable part. 34. The air conditioner according to claim 33, wherein in the first wind direction variable portion, one end is in contact with an upper wall of the blowing path, and the other end is in contact with the second wind direction variable portion. 34. The method of claim 33, wherein the front guide portion for guiding the air discharged by the blower fan forward and downward is provided in the blowing path, and the first wind direction variable portion and the second wind direction variable portion are disposed to extend the upper wall of the front guide portion. Air conditioner. 34. The air conditioner according to claim 33, wherein the lower wall of the blowout port extends outward as an imaginary surface, and the second wind direction variable portion intersects the imaginary surface. 34. The air conditioner according to claim 33, wherein the rotational axis of the second wind direction variable part is located below the rotational axis of the first wind direction variable part. 34. The air conditioner according to claim 33, further comprising a front panel provided with the suction port, and disposing a first wind direction variable portion and a second wind direction variable portion along the front panel. 34. The air conditioner according to claim 33, wherein a first wind direction variable portion is disposed to extend downwardly an upper wall of the blowing path, and a second wind direction variable portion is disposed so that a lower end thereof faces directly downward or rearward downward. 34. The air conditioner according to claim 33, wherein the second wind direction variable part is rotated forward and the direction of the air discharged from the blowout port is changed. The air conditioner of Claim 33 which makes the lower end of a 1st wind direction variable part and the lower end of a 2nd wind direction variable part rotate forward, and delivers the air discharged from the said blower outlet just below the front front downward. 34. The air conditioner according to claim 33, further comprising a third wind direction variable part rotatably supported at a lower portion of the blowout port, and disposing a third wind direction variable part to extend a lower wall of the front guide part. 45. The method of claim 44, wherein the lower end of the third wind direction variable portion is rotated forward, And an air conditioner for delivering the air discharged from the air outlet from the bottom to the front forward and downward. 34. The air conditioner according to claim 33, further comprising an ion generating device for generating ions, wherein the air conditioner sends ions together with air to the room. 34. The air conditioner according to claim 33, wherein the wind direction of the air is varied in the horizontal direction or the front upper direction, and directly under or in the rear downward direction based on the operating condition of the air conditioner or the indoor air condition condition. 48. The air conditioner according to claim 47, wherein the wind direction of the air is varied in the direction immediately below and forward downward, or just below and forward downward, based on the driving condition of the air or the air conditioning condition of the room. 48. The method of claim 47, wherein the air direction of the air when the living room is narrower than a predetermined size is varied horizontally or forwardly above and just below or rearward downward, and when the living room is wider than the predetermined size, the air direction of the air is horizontally or An air conditioner that varies from top to bottom and forward to bottom. 48. The air conditioner according to claim 47, wherein the air speed or the air volume of the air is changed based on the operating condition of the air conditioner or the air condition of the room. 48. The air conditioner according to claim 47, wherein the wind direction of the air is horizontal or forward upward when the operating condition of the air conditioner or the indoor air conditioner is the first condition, and the operating condition of the air conditioner or the indoor air conditioner In the case of this second condition, the wind direction of the air is directly downward or rearward downward, and the air direction of the air is changed to the second condition when the operating condition of the air conditioner or the air conditioning condition of the room is the third condition. Air conditioner made multi onwards. 52. The method of claim 51, wherein the first condition comprises a case where the take-out temperature is lower than a predetermined value, and the second condition consists of a case of a startup state in which the room temperature rises higher than the predetermined value. The condition of 3 is an air conditioner which consists of a stable state where room temperature was stabilized. 48. An ion sensor according to claim 47, further comprising an ion sensor for detecting an ion concentration in a room, The air conditioner of the room which changes a wind direction is based on the ion concentration detected by the said ion sensor. 48. The air conditioner according to claim 47, wherein the air conditioner operation condition in which the wind direction is varied is based on the amount of air sent out from the air outlet. 48. The rotational speed detection unit according to claim 47, wherein a rotation speed detection unit that receives air from the intake port from the intake port and detects the rotational speed of the blower discharged from the air outlet port, wherein the operating condition of the air conditioner that varies the wind direction is determined by the rotation speed detection unit. Air conditioner based on the detection result of. 48. The temperature sensor according to claim 47, wherein the temperature sensor detects a temperature of any one of a temperature of an indoor heat exchanger that exchanges air with blown air to adjust an air temperature, a temperature of air discharged from the blowout port, and a temperature of air blown from the suction port. And an operating condition of the air conditioner for varying the wind direction, based on a detection result of the temperature sensor. 48. The air conditioner according to claim 47, wherein a frequency detector for detecting an operating frequency of the compressor for driving the refrigeration cycle is provided, and an operating condition of the air conditioner for varying the wind direction is based on the detection result of the frequency detector. 48. The air conditioner according to claim 47, wherein a power consumption current detection unit for detecting air conditioning power consumption or current consumption is provided, and an operating condition of the air conditioner for varying the wind direction is based on a detection result of the power consumption detection unit. 48. The air conditioner according to claim 47, wherein the operating condition of the air conditioner in which the outdoor unit receives and heat-exchanges the outside air, and whose air direction is varied, is based on the air volume of the air blown into the outdoor unit. 48. The outdoor unit of claim 47, wherein the outdoor unit has an outdoor blower that blows outside air and provides an outdoor rotation speed detecting unit for detecting the rotational speed of the outdoor blower, wherein the operating condition of the air conditioner for varying the wind direction is the outdoor rotation. The air conditioner based on the detection result of a water detection part. 48. The air conditioner according to claim 47, wherein an air conditioner in a room having a varying wind direction is based on a difference between a detection result of the temperature sensor and a set temperature. 48. The air conditioner according to claim 47, wherein the indoor air conditioner that varies the wind direction is based on the time after the start of heating operation or the size of the living room. 48. The air conditioner according to claim 47, further comprising a humidity sensor for detecting humidity in the room, wherein a condition of air conditioning in a room having a variable wind direction is based on a detection result of the humidity sensor. 48. The air conditioner according to claim 47, further comprising purification degree detection means for detecting a degree of purification of air in the room, wherein a condition of air conditioning in a room having varying wind direction is based on a detection result of the purification degree detection means. The air conditioner according to claim 64, wherein said purification degree detecting means comprises an odor sensor for detecting an odor component contained in indoor air, or a dust sensor for detecting an amount of dust contained in indoor air. 48. The air conditioner according to claim 47, wherein a prohibition means is provided for prohibiting the delivery of air in the rear downward or downward direction.

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