JP2001193985A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioner capable of reducing erroneous actuation when energy saving operation is performed using a plurality of human sensitive sensor. SOLUTION: An air conditioner 10 includes two human sensitive sensors 83A, 83B, and a microcomputer 74 for controlling the air conditioner 10 judges whether or not positions of left and right flaps are directed in any direction of the human sensitive sensors 83A, 83B disposed on the left side and right side of the air conditioner 10, i.e., whether or not the directions of the left and right flaps are substantially coincident to any of directions of the human sensitive sensors 83A, 83B. If the directions of the left and right flaps are substantially coincident with any of the directions of the human sensitive sensors 83A, 83B, a detection result of the human sensitive sensor which is one that is substantially coincident is not employed, and a detection result of the human sensitive sensor that is substantially not coincident to judge whether or not any person is existent.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air conditioner, and more particularly to an air conditioner for conditioning an air-conditioned room provided with an indoor unit.

[0002]

2. Description of the Related Art Air conditioners (hereinafter referred to as "air conditioners").
Air-conditioned air is blown into the room to be air-conditioned by passing through a heat exchanger of an indoor unit (indoor unit) provided in the room to be air-conditioned to blow air into the room to be air-conditioned. ing.

In such an air conditioner, a temperature sensor is provided on a remote control switch for operating the air conditioner, and the air conditioning control is performed so that the temperature mainly detected by the temperature sensor (temperature sensor provided on the remote control switch) becomes a set temperature. By doing so, the temperature around the person in the room to be air-conditioned is set to the set temperature. That is, the remote control switch is operated by a person in the room to be air-conditioned, and the temperature of the remote control switch is close to the sensed temperature of the person in the room to be air-conditioned. Therefore, by setting the temperature detected by the temperature sensor of the remote control switch as the set temperature, it is felt that the room to be air-conditioned is in a comfortable air-conditioning state. Also,
In such an air conditioner, a comfortable air conditioning state can be achieved by controlling the swing of the upper and lower flaps and the left and right flaps to appropriately change the direction in which the temperature-controlled air blows out.

[0004] In recent years, the room to be air-conditioned by an air conditioner, such as a living room, has been increasing in size.
However, from the viewpoint of energy saving, it is not preferable to perform air-conditioning control so that the entire room to be air-conditioned always has the set temperature. That is, for example, when air-conditioning control is performed on a room to be air-conditioned when there is no person in the room to be air-conditioned for a long time, power is consumed wastefully.

For this reason, motion sensors for detecting whether or not there is a person in the room to be air-conditioned are provided on the left and right of the front panel of the air conditioner, respectively.
It detects whether there is a person mainly in the area on the left side toward the air conditioner, and by a human sensor provided on the right side of the front panel,
It is detected whether or not there is a person mainly in the right area toward the air conditioner (step 200 shown in FIG. 11). If the left and right human sensors cannot detect that both persons are present, the air conditioner is detected. An air conditioner that can save energy by stopping the operation of the fan and the compressor (Step 202 shown in FIG. 11) has been proposed.

As described above, by using a plurality of human sensors, it is possible to detect whether or not there is a person in the room to be conditioned over a wide range. And energy saving operation can be achieved.

[0007]

However, in the above prior art, during the swing of the left and right flaps, there is a case where a person is erroneously detected as being present even though the person is not in the room to be air-conditioned. This is because, when the direction in which the left and right flaps are oriented substantially coincides with the direction in which the motion sensor is oriented, for example, a rise in floor temperature or the like due to warm air blown in that direction, or an airflow due to the warm air hitting a wall or the like, for example This is because a human sensor existing in the direction in which the left and right flaps are facing will erroneously detect that there is a person even when there is no person due to a change in the flap. As a result, air conditioning control is performed even when there are no people, and power may be wasted.

The present invention has been made in view of the above-described circumstances, and has as its object to provide an air conditioner that can reduce malfunctions when performing energy saving operation using a plurality of human sensors. I do.

[0009]

The invention according to claim 1 is
A flap is provided at an outlet through which air-conditioned air for air-conditioning the air-conditioned room is blown, and a flap for changing a blowing direction of the air-conditioned air, and a flap is provided near the air outlet and is also provided at each of the air-conditioned rooms. A plurality of detection means for respectively detecting the presence or absence of an infrared radiator in a plurality of detection regions existing in directions, and an operation stop means for stopping the operation of the air conditioner when the infrared radiator is not detected by the detection means Direction detecting means for detecting a direction of blowing by the flap; and detecting stopping means for stopping detecting means corresponding to the detecting area when the direction of blowing by the flap includes at least one detection area of the detecting means. And characterized in that:

[0010] The flap is provided at an outlet through which air-conditioned air for air-conditioning the room to be air-conditioned, for example, hot air or cold air, is blown, and changes a blowing direction of the air-conditioned air. That is, the conditioned air is blown out in the direction in which the flap faces. Changing the blowing direction, that is, turning the flap,
For example, it can be performed by a stepping motor or the like.
In addition, the flap can be rotated, for example, in a substantially horizontal direction or a substantially vertical direction, and can be fixed at an arbitrary position,
It is possible to rotate a predetermined range at a predetermined speed, that is, to swing. Note that the direction of the blowout by the flap is detected by the direction detecting means.

The detecting means includes, for example, a pyroelectric element for detecting far infrared rays condensed by a Fresnel lens, and detects the presence or absence of an infrared radiator from the presence or absence of a change in the detected far infrared rays. This infrared radiator may be, for example, a human as described in claim 3, or may be another animal as long as it emits infrared light.

A plurality of such detecting means are provided near the outlet, for example, in different directions along the rotation direction of the flap. Then, the presence or absence of the infrared radiator in each of the plurality of detection regions existing in the blowing direction in the room to be air-conditioned is detected. That is, when the flap rotates in a substantially horizontal direction, the plurality of detection units are arranged, for example, in different directions along the substantially horizontal direction.
In this way, by arranging the plurality of detection means in different directions, it is possible to respectively detect whether or not the infrared radiator exists in the plurality of detection regions in the room to be air-conditioned.
Detection can be performed over a wide range as compared with the case where detection is performed by one detection unit. In addition, as described in claim 2,
Some of the detection areas corresponding to the plurality of detection means may overlap each other.

The operation stopping means stops the operation of the air conditioner when the infrared radiator is not detected by the detecting means. As a result, wasteful power consumption can be suppressed.

By the way, when detecting whether or not an infrared radiator exists in the room to be conditioned by a plurality of detecting means, when at least one detection area of the detecting means is included in the blowing direction of the flap, for example, conditioned air is blown out. In the case where the direction substantially coincides with the direction of at least one of the detecting means, there may be a case where an infrared radiator is erroneously detected even though there is no infrared radiator due to a change in airflow due to conditioned air.

Therefore, the detection stop means stops the detection means corresponding to the detection area when at least one detection area of the detection means is included in the blowing direction of the flap. For example, it is determined whether or not the direction of the flap substantially matches the direction of at least one detection unit. That is,
For each detection means, it is determined whether or not the direction substantially matches the direction of the flap. For example, when a stepping motor is used for driving the flap, the direction of the flap can be easily determined from the number of pulses supplied to the motor.

If the direction of the flap substantially coincides with the direction of at least one of the detecting means, the detecting means is considered to have a high possibility of erroneous detection. It is invalidated, and it is determined by other detection means whether there is an infrared radiator. Thereby, the reliability of detection of the infrared radiator can be improved. And if it is determined that there is no infrared radiator,
The operation of the air conditioner is stopped by the operation stopping means. As described above, when it is determined that there is no infrared radiator, the air-conditioning operation is stopped, so that it is possible to suppress unnecessary power consumption and to cope with forgetting to turn off the operation switch.

[0017]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below.

FIG. 1 shows an air conditioner (hereinafter referred to as "air conditioner 10") applied to the present embodiment. The air conditioner 10 includes an indoor unit 12 and an outdoor unit 1.
4 and is operated / stopped by operating a wireless remote control switch (hereinafter, referred to as “remote controller 120”). The air conditioner 10 includes a remote controller 1
When operation conditions such as an operation mode and a set temperature are set at 20 and an operation signal is transmitted, the operation signal is received by the indoor unit 12 and operation based on the operation signal is performed.

FIG. 2 shows a refrigeration cycle of the air conditioner 10. The air conditioner 10 includes an indoor unit 12 installed in a room to be air-conditioned and an outdoor unit 1 installed outside the room.
The indoor unit 12 and the outdoor unit 14 are formed by a thick refrigerant pipe 16 for circulating a refrigerant.
A and the refrigerant pipe 16B of a thin tube.

The indoor unit 12 is provided with a heat exchanger 18, and one end of each of the refrigerant pipes 16A and 16B is connected to the heat exchanger 18. The other end of the refrigerant pipe 16A is connected to a valve 20A of the outdoor unit 14. This valve 20A has a muffler 22A
Is connected to the four-way valve 24 via the. This four-way valve 24
Is connected to the compressor 26 via the accumulator 28 and via the muffler 22B.

Further, the outdoor unit 14 is provided with a heat exchanger 30. One end of the heat exchanger 30 is connected to the four-way valve 24 and the other end is connected to the capillary tube 32.
Valve 20 via strainer 34 and modulator 38
B. An electric expansion valve 36 is provided between the strainer 34 and the modulator 38, and the other end of the refrigerant pipe 16B is connected to the valve 20B.
Thereby, a closed circulation path of the refrigerant forming a refrigeration cycle is formed between the indoor unit 12 and the outdoor unit 14.

The air conditioner 10 can perform a cooling operation or a heating operation by circulating the refrigerant in the refrigeration cycle by operating the compressor 26.

That is, in the cooling mode, the refrigerant compressed by the compressor 26 is liquefied by being supplied to the heat exchanger 30, and the liquefied refrigerant is vaporized by the heat exchanger 18 of the indoor unit 12. The air passing through the heat exchanger 18 is cooled. In the heating mode, on the contrary, the refrigerant compressed by the compressor 26 radiates heat by being condensed in the heat exchanger 18 of the indoor unit 12, and the air passing through the heat exchanger 18 by the heat radiated by the refrigerant. Is heated.

In FIG. 2, the arrows indicate the heating operation (heating mode) and the cooling operation (cooling mode or dry mode).
The operation mode is switched between a cooling mode (including a dry mode) and a heating mode by switching the four-way valve 24, and the valve opening degree of the electric expansion valve 36 is controlled to evaporate the refrigerant. The temperature is adjusted. Note that the present invention can be applied to an air conditioner having an arbitrary configuration, and the air conditioner 10 shows one example.

As shown in FIG. 3, the indoor unit 12
The heat exchanger 18 is provided in a casing 42 in which an inlet 46 and an outlet 50 are formed. The casing 42 is fixed to a wall or the like in a room by a base plate 40.

In the casing 42, the heat exchanger 18
A cross-flow fan 44 and a filter 48 are arranged between the suction port 46 and the suction port 46. The air in the room is sucked into the casing 42 by the operation of the cross-flow fan 44,
After passing through the filter 48 and the heat exchanger 18, the air is blown into the room from the air outlet 50. At this time, the air blown into the room passes through the heat exchanger 18 so that heat is exchanged with the refrigerant circulated in the heat exchanger 18, resulting in temperature-controlled air for air-conditioning the room. .

The outlet 50 of the indoor unit 12 is provided with upper and lower flaps 54 together with left and right flaps 52.
The direction of the conditioned air (temperature-controlled air) blown out from the outlet 50 can be changed. That is,
The air blown into the room from the outlet 50 is changed in the vertical direction by the upper and lower flaps 54.
The left and right flaps 52 change the direction of the air blown from the outlet 50 along the left-right direction (horizontal direction). The air conditioner 10 can arbitrarily change the direction of the air blown from the outlet 50 by the upper and lower flaps 54 and the left and right flaps 52.

As shown in FIG. 4, the indoor unit 12
Is provided with a power supply board 56, a control board 58, and a power relay board 60. On a power supply board 56 to which electric power for operating the air conditioner 10 is supplied, a motor power supply 62, a control circuit power supply 64, a serial power supply 66, and a drive circuit 68 are provided. The control board 58 is provided with a serial circuit 70, a drive circuit 72, and a microcomputer 74.

The drive circuit 68 of the power supply board 56 is connected to a fan motor 76 (for example, a DC brushless motor) for driving the cross flow fan 44, and receives a control signal from a microcomputer 74 provided on the control board 58. Drive power is supplied from the motor power supply 62 accordingly. At this time, the microcomputer 74 controls so that the output voltage from the drive circuit 68 is changed in a range of 12 V to 36 V in 256 steps. Thus, the amount of the conditioned air blown out from the outlet 50 of the indoor unit 12 is adjusted.

The drive circuit 72 of the control board 58 is connected to a power relay board 60, a left and right flap motor 77 for operating the left and right flaps 52, and an upper and lower flap motor 78 for operating the upper and lower flaps 54. The power relay board 60 is provided with a power relay 80, a temperature fuse, and the like. The power relay 80 is operated by a signal from the microcomputer 74 to open and close a contact 80A for supplying power to the outdoor unit 14. Air conditioner 1
0 indicates that power can be supplied to the outdoor unit 14 by closing the contact 80A.

The left and right flap motors 77 and 78 are controlled in accordance with control signals from the microcomputer 74 to operate the left and right flaps 52 and the upper and lower flaps 54, respectively. By swinging the left and right flaps 52 in the left and right direction, the blowing direction of the air (air-conditioned air) blown out from the outlet 50 is changed in the left and right direction, and the upper and lower flaps 54 are swung in the vertical direction, thereby changing the indoor unit. The blowing direction of the air (air-conditioned air) blown out from the 12 blowing ports 50 is changed in the vertical direction. The operation of the left and right flaps 52 and the upper and lower flaps 54 can be fixed so that the blowing wind is directed in an arbitrary direction, and can be set so that the wind direction changes randomly.

In the indoor unit 12 of the air conditioner 10, by controlling the rotation of the cross flow fan 44 and the operations of the left and right flaps 52 and the upper and lower flaps 54, the desired air volume and direction or air flow is controlled to make the room comfortable. The air conditioned by the air volume and direction is blown into the room.

As shown in FIG. 4, a serial circuit 70 connected to the microcomputer 74 and the serial power supply 66 of the power supply circuit 56 is connected to the outdoor unit 14,
The microcomputer 74 performs serial communication with the outdoor unit 14 via the serial circuit 70, and controls the operation of the outdoor unit 14.

The indoor unit 12 is provided with a receiving circuit for receiving an operation signal from the remote control switch 120 (see FIG. 1), and a display board 82 provided with an operation display LED and the like. The board 82 is the microcomputer 7
4 is connected. As shown in FIG. 1, a display section 82A of the display board 82 is disposed on the front surface of the casing 42, and the display section 82A includes a remote control switch 120
A receiving unit for receiving an operation signal transmitted from the control unit. Thereby, the remote control switch 120 is set to the display unit 8.
By operating toward 2A, the remote control switch 1
An operation signal from 20 is input to the microcomputer 74.

As shown in FIG. 4, the display substrate 82 is provided with human sensors 83A and 83B for detecting whether there is a person by detecting infrared rays emitted by the person. As shown in FIG. 8, the motion sensors 83A and 83B
Are arranged near both ends of the display unit 82A. Each of the human sensors 83A and 83B includes a human detection sensor having a pyroelectric element for detecting far-infrared rays condensed by the Fresnel lens. Is detected, and the detection result is output to the microcomputer 74.
Output to

As shown in FIG. 9, the motion sensor 83A is disposed to the left in FIG. 9, and is provided with a predetermined angle θ _L (for example, 100 ° ) Can be detected. Further, the human sensor 83B is arranged toward the right side in FIG. 9, and has a predetermined angle θ _R (for example, 100
° ) Can be detected. Thereby, the predetermined angle θ ₀ (for example, 140 °) in the left-right direction centering on the front of the indoor unit 12 ) Can be detected.

As shown in FIG. 4, the microcomputer 74 includes a room temperature sensor 84 for detecting the room temperature and the heat exchanger 1.
8, a heat exchange temperature sensor 86 for detecting the coil temperature is connected, and further, a service LED provided on the control board 58 and an operation changeover switch 88 are connected. The operation changeover switch 88 switches between “normal operation” and “test operation” performed at the time of maintenance or the like, and “stop” that opens the contact of the power switch 88A and shuts off supply of operation power to the air conditioner 10. Can be Normally, the operation changeover switch 88 is set to "normal operation" and the contact of the power switch 88A is closed. The service LED is turned on during maintenance,
The service person is notified of the self-diagnosis result.

The indoor unit 12 includes an outdoor unit 14
A terminal block 90 is provided to which wiring is connected. Terminals 90A, 90B, 90 of this terminal block 90
To C, wiring for power supply from the indoor unit 12 to the outdoor unit 14 and wiring for performing serial communication between the indoor unit 12 and the outdoor unit 14 are connected.

As shown in FIG. 5, the outdoor unit 14
Is provided with a terminal block 92, and terminals 92A, 92B, 92C of the terminal block 92 are connected to terminals 90A, 90B, 9 of the terminal block 90 of the indoor unit 12, respectively.
0C. The outdoor unit 14 is provided with a rectifying board 94 and a control board 96. The control board 96 is provided with a microcomputer 98, noise filters 100A, 100B, 100C, a serial circuit 102, a switching power supply 104, and the like.

The rectifying board 94 includes a noise filter 100
The power supplied via A is double-voltage rectified, and the smoothed DC power is output to the switching power supply 104 via the noise filters 100B and 100C. The switching power supply 104 is connected to an inverter circuit 106 together with the microcomputer 98, and the inverter circuit 106 is connected to a compressor motor 108. Inverter circuit 1
Reference numeral 06 outputs electric power having a frequency corresponding to the control signal output from the microcomputer 98 to the compressor motor 108, and drives the compressor 26 to rotate.

The microcomputer 98 is connected to the inverter circuit 1
The frequency of the power output from 06 is off or 14Hz
The control is performed so as to be in the range described above (the upper limit is determined by the upper limit of the operating current).
08, that is, the rotation speed of the compressor 26 is changed,
The operating capacity of the compressor 26 (the cooling / heating capacity of the air conditioner 10) is controlled.

The control board 96 includes a four-way valve 2
4 and a fan motor 110 for driving a blower fan (not shown) for cooling the heat exchanger 30 and a fan motor condenser 110A. The outdoor unit 14 has an outside air temperature sensor 11 for detecting an outside air temperature.
2. A coil temperature sensor 114 for detecting the temperature of the refrigerant coil of the heat exchanger 30 and a compressor temperature sensor 116 for detecting the temperature of the compressor 26 are provided, and these are connected to the microcomputer 98. Microcomputer 98
Switches the four-way valve 24 in accordance with the operation mode, and controls the fan motor 11 based on the control signal from the indoor unit 12 and the detection results of the outside air temperature sensor 112, the coil temperature sensor 114, and the compressor temperature sensor 116.
On / off of 0, the operating frequency of the compressor motor 108 (the capacity of the compressor 26) and the like are controlled.

A motor 118 for driving the electric expansion valve 36 to open and close is connected to the control board 96. The microcomputer 98 controls the opening of the electric expansion valve 36 by the motor 118.

FIGS. 6A and 6B show an example of a remote control 120 used for remote control of the air conditioner 10. FIG.

The remote control 120 is provided with a display window 124 using a rectangular liquid crystal panel in a casing 122. As shown in FIG. 6B, various operation conditions such as an operation mode, a set temperature, a room temperature (room temperature), and an air volume can be displayed on the display window 124. FIG. 6 (A)
As shown in FIG. 1, during the operation of the air conditioner 10, set operating conditions or operating conditions, such as an operating mode, a set temperature or room temperature, and an air volume, are selected and displayed.

As shown in FIGS. 6A and 6B, a start / stop button 1 is provided on the surface of the casing 122.
26, temperature setting buttons 128A, 128B, one hour timer (1H timer) button 130, energy saving mode (hereinafter,
One-touch eco button 132 for setting operating conditions (eco-mode), an operation switching button 138 for sequentially switching the operation mode among automatic, heating, dry, cooling, air blowing, and air cleaning, and blowing out from the outlet 50 of the indoor unit 12. An air volume button 140 for switching the setting of the air volume, a wind direction button 142 for switching the setting of the direction and operation of the left and right flaps 52 and the upper and lower flaps 54 from the outlet 50 of the indoor unit 12, and a comfortable sleep can be obtained. A sleep button 144, an amp switching button 146, a timer on button 150, a timer off button 152, and a timer setting button 154 are provided to enable various settings of the operating capacity of the air conditioner 10. Further, a display corresponding to these operations is made on the display window 124 (for example, see FIG. 6A).

The air conditioner 10 has a run / stop button 126
Is operated / stopped by the operation of. The display window 124
Is increased by operating the temperature setting button 128A, and is decreased by operating the temperature setting button 128B.

The one-hour timer button 130 is
The operation time of 0 is set to one hour, and when one hour elapses, a stop signal is transmitted from the remote controller 120 to the indoor unit 12 of the air conditioner 10.

The setting of the one-touch eco button 132 is stored even when the one-touch eco button 132 is pressed while the operation is stopped. Therefore, the one-touch eco button 13
When the operation is started after pressing 2, the eco mode is automatically set. Conversely, the setting is stored even when the operation is stopped by pressing the one-touch eco button 132 during driving, and the eco mode is automatically set when the driving is started again. That is, the setting and cancellation of the eco mode can be performed only by operating the one-touch eco button 132. The eco mode operates in each of the cooling, heating, dry, and automatic operation modes.

The amperage switching button 146 is used to switch the upper limit setting of the used electric capacity. For example, the upper limit of the used electric capacity can be changed from 20 amps to 15 amps. As a result, the maximum current value can be saved, so that the breaker down can be prevented even when the electric appliance is used together with another electric appliance. Button 1 with timer
The timer 50 and the timer-off button 152 are used to set the operation start time and the operation stop time. After displaying the desired time, the timer is reserved by operating the timer setting button 154.

The casing 122 of the remote controller 120
Is provided with a cover 134.
4, the reset button 156 and the sensor switching button 158 are exposed as shown in FIG.

FIG. 7 is a functional block diagram of the remote controller 120. The remote controller 120 has a display section 160 for displaying the display window 120, an operation section 162 provided with the various setting buttons described above, A room temperature sensor 164 for detecting the room temperature and a timer circuit 166 having a clock function for measuring time are provided, and these are connected to a remote controller 168 including a microcomputer. The remote control unit 168 includes the indoor unit 12.
A transmission unit 170 for transmitting an operation signal to the control unit is connected.

The remote controller 168 sends an operation signal of the air conditioner 10 according to the operation state input from the operation unit 162 to the indoor unit 12 and
4 is also transmitted. Further, the remote control controller 168 confirms whether or not the indoor unit 12 is operating. This confirmation is made based on, for example, a reception response from the indoor unit 12 when an operation signal is transmitted.

When the timer of the operation of the air conditioner 10 is reserved, the remote controller 168 stores the reservation, and automatically sends an operation / stop signal to the indoor unit 12 according to the reservation. Operate air conditioner 10 /
It is designed to stop.

The operation of the present embodiment will be described below.

In the air conditioner 10, the main remote controller 120
When an operation / stop operation is performed in a state set to one of the cooling operation, the dry operation, the heating operation, and the like by operating the switch, the operation in the set operation mode is started.

When the air conditioner 10 is operated to start the air conditioning operation, the set temperature and the indoor temperature are measured, and based on the measurement results, the operating frequency of the compressor 26, the air volume (the number of rotations of the cross flow fan) and the like are determined. The air conditioning operation is performed based on the setting result.

In the outdoor unit 14, the four-way valve 24 is switched according to the set operation mode. For example, when the cooling mode or the dry mode is set, the compressor 2
The refrigerant compressed by 6 is supplied to the heat exchanger 30 of the outdoor unit 14. Thereby, the refrigerant compressed by the compressor 26 is liquefied by passing through the heat exchanger 30, and the liquefied refrigerant is supplied to the heat exchanger 18 of the indoor unit 12. The refrigerant supplied to the heat exchanger 18 of the indoor unit 12 evaporates when passing through the heat exchanger 18 and cools the air passing through the heat exchanger 18.

On the other hand, during the heating operation, the compressor 26
The four-way valve 24 is switched so that the high-pressure refrigerant compressed by the above is supplied to the heat exchanger 18 of the indoor unit 12. Thereby, when the high-pressure refrigerant compressed by the compressor 26 is liquefied in the heat exchanger 18, the air passing through the heat exchanger 18 is heated. The room heated by the air heated by the heat exchanger 18 is blown out from the outlet 50 into the room.

By the way, the blowing direction of the temperature-controlled air can be changed in the left-right direction and the up-down direction by setting with the wind direction button 142 of the remote controller 120. In the air conditioner 10, the blowing direction is fixed in a desired direction, that is, the left and right flaps 52 or the upper and lower flaps 54 are fixed at a predetermined angle, and the wind direction is changed at random, ie, the left and right flaps 52 or the upper and lower flaps 54 are fixed. You can swing at speed. This is controlled by the microcomputer 74.

The control of the microcomputer 74 when the wind direction changes randomly in the left-right direction (horizontal direction), that is, the setting in which the wind direction swings in the left-right direction will be described below with reference to the flowchart shown in FIG.

In step 100 shown in FIG. 10, the microcomputer 74 determines whether or not the position of the left and right flaps 52 is directed to the direction of the human sensor 83A disposed on the left side of the air conditioner 10, that is, the direction of the left and right flaps 52 is determined. It is determined whether or not the direction of the human sensor 83A is substantially the same, for example, whether or not the direction of the left and right flaps 52 is within a range of a predetermined angle θ _CL about the direction of the human sensor 83A. . For example, when a stepping motor is used as the flap motor, the positions of the left and right flaps 52 are centered on the direction in which the human sensor 83A is oriented so that the directions of the left and right flaps 52 can be easily determined by the number of pulses given to the motor. Is within the range of the predetermined angle θ _CL , the result is affirmative in step 100, and in the next step 102, the air conditioner 1
The detection result obtained by the human sensor 83B disposed on the right side of “0” is fetched.

In the next step 104, the area on the right side of the air conditioner 10
That is, it is determined whether or not there is a person in the range of θ _R in FIG. If it is determined that there are people, step 1
When the result is affirmative in step 04, the process returns to step 100. On the other hand, if it is determined that there is no person, the result in step 104 is negative,
In step 106, the operation is stopped. That is, the cross flow fan 44 and the compressor 26 are stopped.

That is, when the direction of the left and right flaps 52 substantially coincides with the direction of the human sensor 83A,
It is determined that the human sensor 83A has a high possibility of erroneous detection due to a change in airflow or the like, and it is determined whether or not there is a person only from the detection result of the human sensor 83B.

If the direction of the left and right flaps 52 is out of the range of the predetermined angle θ _CL about the direction in which the human sensor 83A faces, the result in step 100 is NO, and the position of the left and right flaps 52 is determined in the next step 108. Is directed in the direction of the human sensor 83B disposed on the right side of the air conditioner 10, that is, whether the direction of the left and right flaps 52 substantially matches the direction in which the human sensor 83B is directed, for example, the left and right flaps 52 Is determined to be within the range of the predetermined angle θ _CR about the direction in which the human sensor 83B faces.

The direction of the left and right flaps 52 is the human sensor 83
If B is within the range of the predetermined angle θ _{CR about} the direction in which B is oriented, the result in step 108 is affirmative, and the next step 1
10, a human sensor 83 arranged on the left side of the air conditioner 10
The detection result by A is taken in.

In the next step 104, the area on the left side of the air conditioner 10
That is, it is determined whether or not there is a person in the range of θ _L in FIG. If it is determined that there are people, step 1
When the result is affirmative in step 04, the process returns to step 100. On the other hand, if it is determined that there is no person, the result in step 104 is negative,
In step 106, the operation is stopped.

That is, when the direction of the left and right flaps 52 substantially coincides with the direction of the human sensor 83B,
It is determined that there is a high possibility that the human sensor 83B will make an erroneous detection due to a change in airflow or the like.

If the direction of the left and right flaps 52 is out of the range of the predetermined angle θ _CR about the direction in which the human sensor 83B faces, the result in step 108 is NO, and in the next step 112, the human sensor 83A, The detection result by 83B is taken.

Then, in the next step 104, it is determined from the detection results by the human sensors 83A and 83B whether or not there is a person in the range of θ ₀ in FIG. If it is determined that there is a person, the result is affirmative in step 104 and step 10
Return to 0. On the other hand, when it is determined that there is no person, the result in Step 104 is negative, and the operation is stopped in Step 106.

That is, when the direction of the left and right flaps 52 does not substantially coincide with the direction of the human sensor 83A or the direction of the human sensor 83B, the human sensor 83
It is determined that the possibility of erroneous detection is low for both A and 83B, and it is determined whether there is a person using the detection results of both.

As described above, the detection result of the human sensor that substantially matches the direction of the left and right flaps 52 is invalidated, and the presence or absence of a person is determined using the detection results of other human sensors. Can be prevented. Therefore, energy saving operation can be performed more reliably.

In the present embodiment, a case where two motion sensors are used has been described as an example. However, it is needless to say that the present invention can be applied to a case where three or more motion sensors are used. Absent. In the above description, the case where the left and right flaps 52 are swinging has been described as an example. However, the present invention can be applied to a case where the left and right flaps 52 are fixed.

[0074]

As described above, according to the present invention, when the direction of the flap substantially coincides with the direction of at least one of the detecting means, the detecting means is stopped, and infrared light is emitted by the other detecting means. It is determined whether or not there is a body, and if it is determined that there is no infrared radiator, the operation stop means stops the operation of the air conditioning, so that the reliability of detection of the infrared radiator can be improved. As a result, it is possible to obtain the effect of suppressing unnecessary power consumption.

[Brief description of the drawings]

FIG. 1 is a schematic perspective view showing an indoor unit and a remote control switch applied to the present embodiment.

FIG. 2 is a schematic diagram showing a refrigeration cycle of an air conditioner applied to the present embodiment.

FIG. 3 is a schematic sectional view showing the inside of the indoor unit.

FIG. 4 is a schematic block diagram illustrating a configuration of a substrate in the indoor unit.

FIG. 5 is a schematic block diagram illustrating a configuration of a substrate of the outdoor unit.

FIGS. 6A and 6B are schematic plan views each showing a remote controller, wherein FIG. 6A shows a state where a slide cover is opened, and FIG. 6B shows a state where the slide cover is closed.

FIG. 7 is a schematic block diagram of a remote controller.

FIG. 8 is a diagram for describing an arrangement of a human sensor.

FIG. 9 is a diagram for explaining a range in which a human sensor can detect a person.

FIG. 10 is a flowchart of a control routine executed by the microcomputer of the indoor unit according to the present invention.

FIG. 11 is a flowchart of a control routine executed by a microcomputer of a conventional indoor unit.

[Explanation of symbols]

Reference Signs List 10 air conditioner (operation stop means, detection stop means, direction detection means) 12 indoor unit 14 outdoor unit 18 heat exchanger 26 compressor 50 outlet 52 left / right flap (flap) 74 microcomputer 77 left / right flap motor 82 display substrate 83A, 83B Sensor (detection means) 84 Room temperature sensor 120 Remote control

Claims (3)

[Claims] 1. A flap that is provided at an outlet through which air-conditioned air for air-conditioning a room to be air-conditioned is blown out and that changes a blowing direction of the air-conditioned air; A plurality of detecting means for respectively detecting the presence or absence of an infrared radiator in a plurality of detection regions present in a blowing direction in the room to be air-conditioned; and operating the air conditioning when the infrared radiator is not detected by the detection means. Operation stop means for stopping, direction detecting means for detecting a blowing direction by the flap, and detecting means corresponding to the detecting area when at least one detecting area of the detecting means is included in the blowing direction by the flap. An air conditioner comprising: a detection stop means for stopping; 2. The air conditioner according to claim 1, wherein a part of a detection area corresponding to each of the plurality of detection means overlaps each other. 3. The air conditioner according to claim 1, wherein the infrared radiator is a person.