JP5156708B2 - Air conditioner - Google Patents

Description

  The present invention relates to an air conditioner having a function of detecting the ambient temperature of a remote controller.

  The air conditioner circulates room air through a heat exchanger, adjusts it by a heating, cooling, dehumidifying function, and the like, and blows out the adjusted conditioned air into the room to air-condition the room. At this time, if the user's position is detected and conditioned air is sent to control the temperature around the user, the user can omit troublesome operations such as changing the temperature setting and changing the wind direction setting. As a result, the degree of satisfaction of the user increases, and only the surroundings of the user are comfortably air conditioned, so that energy saving of the air conditioner can be achieved.

  As one of the methods, the air conditioner is equipped with a remote controller (hereinafter referred to as remote control) temperature and position detection function, and the position of the remote control placed near the user is regarded as the position of the user. A method for controlling the air direction, the air volume, the heating / cooling capacity and the like according to the temperature and position of the remote controller is disclosed.

Japanese Patent Laid-Open No. 2007-244793 discloses a temperature sensor, a room temperature display unit, a temperature setting unit, a set temperature display unit, a control target temperature setting unit, and a power-up for changing the control target temperature. A remote control for an air conditioner is disclosed in which a control target temperature is increased / decreased by operating a power-up / down SW to increase / decrease a control target temperature to bring a room temperature in the vicinity of the remote control to a temperature desired by the user.
That is, a remote controller for an air conditioner is disclosed in which the room temperature in the vicinity of the remote controller that is always placed near the user is set to a temperature required by the user.

In Patent Document 2 (Japanese Patent No. 3078350), when a predetermined time (10 minutes) elapses after the remote controller (remote controller) is operated, the operation control means of the remote controller is a room temperature sensor provided in the remote controller. An air conditioner is disclosed in which room temperature data is transmitted to an indoor unit, and when a predetermined time (10 hours) elapses without the remote controller being operated, the operation control means of the remote controller stops transmitting room temperature data. .
This eliminates unnecessary transmission of room temperature data from the remote controller, extends the life of the battery built in the remote controller, and shortens the transmission cycle to perform fine air conditioning control. Has been.

In Patent Document 3 (Japanese Patent Application Laid-Open No. 2007-127348), wireless data is transmitted, an environmental condition command transmitted from the remote controller and distance information between the environmental equipment and the remote controller are received, and the remote controller receives the distance information according to the distance information. An environmental adjustment system that corrects a commanded environmental command condition is disclosed.
As a result, in the environmental equipment such as air conditioning equipment and lighting equipment in the floor divided into a plurality of zones, distance information with these environmental equipment is obtained, and the environmental adjustment factors affected by the distance are corrected, thereby An environmental adjustment system that easily and reliably obtains environmental conditions more suitable than those of the prior art is disclosed.

JP 2007-247983 A Japanese Patent No. 3078350 JP 2007-127348 A

Currently, home air conditioners require environmental considerations and are strongly required to save resources and energy.
In Patent Document 1, when the power-up / down switch provided on the remote control is turned on, a control target temperature different from the set temperature is determined by the remote control and sent to the air conditioner body. Since the control target temperature is determined unilaterally by ignoring it, the operation of the air conditioner may become unstable.
Japanese Patent Application Laid-Open No. 2004-228561 is an alternative to suppressing battery consumption of the remote control between intermittent transmission and transmission stop, and does not touch on suppression of battery consumption of the remote control during intermittent transmission until transmission stop.
Patent Document 3 adjusts the environmental conditions of the place where the remote control is located according to the remote control temperature and the remote control position, but does not specifically mention the degree of adjustment, and air conditioning control may become unstable. There is.

  Therefore, the present invention is suitable for resource saving and energy saving, and the heating power and / or the cooling power is appropriately set so that the temperature around the remote control where the user is close to the set temperature without requiring troublesome operation by the user. It is an object to provide a controlled air conditioner.

  In order to solve such a problem, the present invention provides an air conditioner according to claim 1 that includes a remote control temperature sensor in a remote controller that inputs a set temperature and an operation instruction, and a suction air temperature sensor in the air conditioner body. A temperature shift value determined according to the remote control temperature detected by the remote control temperature sensor and the suction air temperature detected by the suction air temperature sensor is added to the set temperature so that the suction air temperature approaches the set temperature. In the air conditioner for controlling the heating power and / or the cooling power, the transmission interval for transmitting the remote control temperature detected by the remote control temperature sensor to the air conditioner body is set to the intake air temperature, the remote control temperature, and the temperature shift. The remote controller determines the remote controller temperature according to the determined transmission interval. And transmits to.

  According to the present invention, the heating power and / or the cooling power is appropriate so that the temperature around the remote controller where the user is close to the set temperature without requiring a troublesome operation for the user while being suitable for resource saving and energy saving. It is possible to provide an air conditioner that is controlled by the above.

1 is an overall configuration diagram of an air conditioner according to an embodiment. It is side surface sectional drawing of the indoor unit which comprises the air conditioner which concerns on this embodiment. It is a block diagram of the indoor unit transmission / reception part of the indoor unit which comprises the air conditioner which concerns on this embodiment. It is an external appearance front view of the remote control which constitutes the air harmony machine concerning this embodiment. It is a block diagram of the remote control transmission / reception part of the remote control which comprises the air conditioner which concerns on this embodiment. It is a flowchart of remote control temperature reference control of the remote control. It is a flowchart of remote control temperature reference control of an indoor unit. It is a detection area division figure of the room in which the indoor unit was installed.

  Hereinafter, modes for carrying out the present invention (hereinafter referred to as “embodiments”) will be described in detail with reference to the drawings as appropriate. In addition, the same code | symbol in a figure shall show the same thing or an equivalent.

≪Overall configuration of air conditioner≫
First, the whole structure of the air conditioner 1 which concerns on this embodiment is demonstrated using FIG. FIG. 1 is an overall configuration diagram of an air conditioner according to the present embodiment.
The air conditioner 1 that harmonizes the air in the room includes an indoor unit 2 that is installed indoors, an outdoor unit 6 that is installed outdoors, a remote controller 4 that remotely controls the air conditioner 1, an indoor unit 2, and an outdoor unit 6. And a connecting pipe 8 connecting the two.

<Outdoor unit>
The outdoor unit 6 includes a compressor (not shown), an outdoor blower (not shown), an outdoor heat exchanger (not shown), and the like. The compressor and outdoor heat exchanger of the outdoor unit 6 are connected to an indoor heat exchanger 33 (see FIG. 2) of the indoor unit 2 to be described later by two refrigerant pipes (not shown) of the connection pipe 8. It functions as a heat pump by circulating.

<Indoor unit>
Next, the indoor unit 2 which comprises the air conditioner 1 which concerns on this embodiment is demonstrated using FIG. 1 and FIG.
FIG. 2 is a side cross-sectional view of the indoor unit constituting the air conditioner according to the present embodiment.
The indoor unit 2 includes an indoor heat exchanger 33 at the center of the housing base 21 and a cross-flow fan type indoor fan 34 having a length substantially equal to the width of the indoor heat exchanger 33 on the downstream side of the indoor heat exchanger 33. And a dew receiving tray 35 that receives the condensed water condensed in the indoor heat exchanger 33.
Further, basic internal structures such as filters 271 and 271 ′, upper and lower wind direction plates 291 and 292, and left and right wind direction plates 295 are attached to the housing base 21 of the indoor unit 2. By covering these with the decorative frame 23 and attaching the front panel 25 to the front surface of the decorative frame 23, the indoor unit 2 is configured by being enclosed in the casing 20 including the casing base 21, the decorative frame 23, and the front panel 25.

  When the indoor blower fan 34 rotates, indoor air flows from the air inlet 27 provided in the indoor unit 2 to the indoor heat exchanger 33. The conditioned air whose temperature and humidity have been adjusted by the indoor heat exchanger 33 flows through the indoor blower fan 34 to the blowout air passage 290 having a width substantially equal to the length of the indoor blower fan 34. Thereafter, the conditioned air is deflected left and right by the left and right wind direction plates 295 arranged in the middle of the blowout air passage 290, and is additionally deflected indoors by the up and down airflow direction plates 291 and 292 arranged at the air blowing port 29. Blow out.

The air suction port 27 includes an upper air suction portion 270 provided in the upper part of the indoor unit 2 and a front air suction portion 270 ′ provided in the front surface of the indoor unit 2.
Here, the movable panel 251 provided on the front panel 25 is rotated by a drive motor (not shown) with a rotation shaft provided at the lower end as a fulcrum, and the front air suction portion 270 is operated when the air conditioner 1 is operated. 'It is configured to open. Accordingly, the indoor air is also sucked into the indoor unit 2 from the front air suction part 270 ′ when the air conditioner 1 is operated. In addition, when the operation of the air conditioner 1 is stopped, the movable panel 251 is rotated so that the front air suction part 270 ′ is closed.
The filters 271 and 271 ′ are for removing dust contained in room air sucked from the air suction port 27 (upper air suction part 270 and front air suction part 270 ′). It arrange | positions so that the suction side may be covered.

  The dew tray 35 is disposed below the lower ends of the front and rear sides of the indoor heat exchanger 33, and is provided to receive condensed water generated in the indoor heat exchanger 33 during cooling operation or dehumidifying operation. The condensed water collected in the dew tray 35 is discharged to the outside through a drain pipe (not shown) provided inside the connection pipe 8.

The air outlet 29 formed on the lower surface of the decorative frame 23 is disposed adjacent to the divided portion of the front panel 25 and the decorative frame 23, and communicates with the outlet air passage 290 inside the indoor unit 2.
The two up and down wind direction plates 291 and 292 are required at the time of operation of the air conditioner 1 by a drive motor (not shown) in response to an instruction from the remote controller 4 with pivot shafts provided at both ends as fulcrums. It is rotated to an angle, and the air outlet 29 is opened and held in that state. When the operation of the air conditioner 1 is stopped, the vertical wind direction plates 291 and 292 are controlled so as to close the air outlet 29. In addition, the up-and-down air direction plates 291 and 292 are configured to be concealed from the blowing air passage 290 and to be continuous with the bottom surface of the indoor unit 2 in the closed state.
The left and right wind direction plates 295 are rotated to a required angle by a drive motor (not shown) in response to an instruction from the remote controller 4 with a rotation shaft provided at the lower end as a fulcrum, and are held in that state. .
As described above, the indoor unit 2 of the air conditioner 1 rotates the up and down wind direction plates 291 and 292 and the left and right wind direction plates 295 to a required angle in accordance with an instruction from the remote controller 4 to send the conditioned air to the air outlet. It is deflected up and down and left and right from 29 and blown out in a desired direction.
In addition, by instructing from the remote controller 4, the up and down wind direction plates 291 and 292 and the left and right wind direction plates 295 are periodically oscillated during the operation of the air conditioner 1, and the conditioned air is periodically blown out over a wide range in the room. Is possible.

The indoor unit 2 includes an indoor unit thermistor 211 that detects the temperature of indoor air sucked into the indoor unit 2 from the air suction port 27 (hereinafter referred to as “suction air temperature”) near the front air suction part 270 ′. .
The indoor unit 2 may include an indoor humidity sensor (not shown) that detects the humidity of the indoor air sucked into the indoor unit 2 from the air suction port 27.

  On the lower side of the front panel 25 of the indoor unit 2, an indoor unit transmission / reception unit 380 for transmitting and receiving infrared signals between the indoor unit 2 and the remote controller 4, and a display for displaying the operating status of the air conditioner 1 A device 390 is arranged.

Here, the configuration of the indoor unit transmission / reception unit 380 will be described with reference to FIG.
FIG. 3 is a configuration diagram of an indoor unit transmission / reception unit of the indoor unit that constitutes the air conditioner according to the present embodiment.
The indoor unit transmission / reception unit 380 includes an IR receiver 381 that receives an infrared signal from the remote controller 4, a central transmission element 382 that transmits an infrared signal toward the center of the room in which the indoor unit 2 is installed, The left transmission element 383 that transmits an infrared signal toward the left side of the installed room and the right transmission element 384 that transmits an infrared signal toward the right side of the room where the indoor unit 2 is installed.

The indoor unit 2 includes a control board (not shown) in an internal electrical component box (not shown), and a microcomputer (not shown) and a storage device (not shown) are provided on the control board. Yes.
The microcomputer receives signals from various sensors such as the indoor unit thermistor 211 and the indoor humidity sensor, and also receives an infrared signal from the remote controller 4 via the indoor unit light transmitting / receiving unit 380 (IR receiver 381).
Based on these signals, the microcomputer controls the drive motor for the indoor blower fan 34, the drive motor for the movable panel 251, the drive motors for the up / down air direction plates 291 and 292, the drive motor for the left / right air direction plates 295, and the connection piping. It controls communication with the outdoor unit 6 (compressor, outdoor blower, etc.) via the 8 electric wires, and controls the indoor unit 2 and the outdoor unit 6 in an integrated manner.
Further, the microcomputer can transmit an infrared signal to the remote controller 4 via the indoor unit transmission / reception unit 380 (central transmission element 382, left transmission element 383, right transmission element 384).

<Remote control>
Next, the remote controller 4 constituting the air conditioner 1 according to the present embodiment will be described with reference to FIGS. 4 and 5.
FIG. 4 is an external front view of the remote controller that constitutes the air conditioner according to the present embodiment.
The remote controller 4 includes an operation panel 403 having a plurality of operation buttons for instructing the air conditioner 1 (see FIG. 1) and a liquid crystal display screen (hereinafter referred to as LCD (Liquid) for displaying the operation instructions of the air conditioner 1 and the like. (Referred to as Crystal Display) 402 and a remote control light transmitting / receiving unit 401 that communicates with the indoor unit 2 (see FIG. 1) by an infrared signal.
The remote control light transmitting / receiving unit 401 is formed with a thermistor ventilation path 410 through which indoor air can be ventilated into the remote control light transmitting / receiving unit 401.

Here, the configuration of the remote control light transmitting / receiving unit 401 will be described with reference to FIG.
FIG. 5 is a configuration diagram of a remote control transmission / reception unit of a remote control constituting the air conditioner according to the present embodiment. In addition, it is the state which removed the cover which permeate | transmits the infrared rays in which the thermistor ventilation path 410 of the remote control light transmission / reception part 401 was formed.
The remote control light transmission / reception unit 401 receives an infrared signal from the IR receiver 421 that receives an infrared signal from the indoor unit transmission / reception unit 380 (see FIG. 1) of the indoor unit 2 and the indoor unit transmission / reception unit 380 of the indoor unit 2. A transmission element 422 for transmission and a remote control thermistor 411 for detecting the air temperature around the remote control 4 (hereinafter referred to as “remote control temperature”) via the thermistor ventilation path 410 are provided.

Accordingly, the remote controller 4 can transmit an infrared signal to the indoor unit 2 via the remote control light transmitting / receiving unit 401 (transmitting element 422) with respect to the set temperature and the operation instruction set by the user operating the operation panel 403. It becomes. Further, the remote control temperature detected by the remote control thermistor 411 can also transmit an infrared signal to the indoor unit 2 via the remote control light transmitting / receiving unit 401 (transmitting element 422). In addition, the remote controller 4 can receive an infrared signal from the indoor unit 2 via the remote controller transmission / reception unit 401 (IR receiver 421).
As described above, the remote control 4 is a wireless system using an infrared light emitting element so that the user can operate the air conditioner 1 wherever in the room, and the remote control 4 has a power supply for infrared communication and display. A battery (not shown) for supplying the battery is incorporated.

≪Indoor temperature control of air conditioner≫
The indoor temperature of the air conditioner is controlled based on the set temperature set by the user using the remote controller 4 and the intake air temperature detected by the indoor unit thermistor 211.
However, since the indoor unit 2 is generally mounted at a high place in the room, the intake air temperature detected by the indoor unit thermistor 211 and the air temperature around the user are not necessarily the same, and a slight temperature difference occurs. .
Therefore, in consideration of this temperature difference, an additional set temperature obtained by adding a predetermined temperature shift value to the set temperature set by the user using the remote controller 4 (that is, the added set temperature = set temperature + temperature shift value), By controlling the capacity of the air conditioner 1 in accordance with the difference between the intake air temperature detected by the indoor unit thermistor 211 and controlling the intake air temperature to be quickly increased to the set temperature, the ambient air around the user Bring the temperature closer to the set temperature.
The temperature shift value is a value stored in a storage device of a microcomputer provided in the indoor unit 2, and takes different values depending on the structure of the air conditioner 1 and the type of operation such as heating / cooling.

Next, a method for updating the temperature shift value using the remote control temperature detected by the remote control thermistor 411 of the remote control 4 and performing air conditioning will be described with reference to FIGS. 6 and 7.
FIG. 6 is a flowchart of remote controller temperature reference control of the remote controller. FIG. 7 is a flowchart of indoor unit remote controller temperature reference control.

<Remote control temperature reference control flow (remote control)>
The remote controller temperature reference control of the remote controller 4 will be described with reference to FIG.

  When a user presses an operation button for giving an operation instruction to the air conditioner 1 provided on the operation panel 403 of the remote controller 4, the remote controller 4 transmits an infrared signal indicating the operation mode and the set temperature to the indoor unit 2. (Step S101). The “operation mode” includes operation settings such as cooling and heating, air volume settings, and wind direction settings.

  Next, the remote controller 4 activates the IR receiver 421 of the remote control light transmitting / receiving unit 401, and sets the reception permission state in which the infrared signal from the indoor unit 2 can be received (step S104).

When the IR receiver 421 receives the infrared signal indicating the next timing transmitted from the indoor unit 2 (step S105), the remote controller 4 stops the IR receiver 421 and sets the reception prohibited state in which the infrared signal from the indoor unit 2 is not received. (Step S106).
Here, “next timing” indicates a time for transmitting the remote controller temperature detected by the remote controller thermistor 411 from the remote controller 4 to the indoor unit 2. The next timing may be a relative time or an absolute time, and may take any form as long as the time at which the remote controller 4 transmits the next remote controller temperature can be specified.
In the present embodiment, the case where the next timing is a signal indicating an absolute time will be described below.

The remote controller 4 shifts to a sleep mode in which functions other than the timer operation are suppressed until the time of the next received timing elapses, and suppresses consumption of the built-in battery of the remote controller 4 (step S107).
However, when the operation button on the operation panel 403 of the remote controller 4 is pressed, the sleep mode is quickly exited and the normal operation is resumed.

  When the next timing elapses, the remote controller 4 returns from the sleep mode, detects the remote controller temperature with the remote controller thermistor 411 (step S108), and transmits an infrared signal indicating the detected remote controller temperature to the indoor unit 2 (step S108). S109), the process returns to step S104.

The remote controller temperature in step S108 may be detected a plurality of times at appropriate time intervals, and the average value may be obtained.
In addition, when performing temperature detection a plurality of times, when the temperature detection time interval is long, the remote controller temperature detection and the sleep mode may be alternately repeated to suppress the consumption of the internal battery.

As described above, the remote controller 4 is activated only for a short time from detection of the remote controller temperature (step S108) to reception of the next timing and prohibition of reception of the IR receiver 421 (step S106), and most of the time is set to the sleep mode. Transition (step S107).
Further, the IR receiver 421 is activated only for a very short time from step S104 to step S106, and the IR receiver 421 is stopped during other times.
As a result, the remote controller 4 consumes very little built-in battery and can extend the battery life.

<Remote control temperature reference control flow (indoor unit)>
Next, the remote controller temperature reference control of the indoor unit 2 will be described with reference to FIG.
The microcomputer of the indoor unit 2 receives the infrared signal indicating the operation mode and the set temperature transmitted from the remote controller 4 in step S101 (see FIG. 6) via the indoor unit transmission / reception unit 380 (step S201).

  The microcomputer of the indoor unit 2 transmits an infrared signal indicating the next timing for the first time stored in the storage device of the microcomputer via the indoor unit transmission / reception unit 380 (step S204). The infrared signal indicating the next timing transmitted from the indoor unit 2 is received by the remote controller 4 in step S105 (see FIG. 6).

The microcomputer of the indoor unit 2 controls the indoor unit 2 according to the operation mode, set temperature, and the like from the remote controller 4 and starts the operation of the air conditioner 1.
Further, the microcomputer of the indoor unit 2 waits to receive an infrared signal indicating the remote controller temperature from the remote controller 4 (No in step S205).

When the microcomputer of the indoor unit 2 receives the infrared signal indicating the remote controller temperature from the remote controller 4 via the indoor unit light receiving / receiving unit 380 (Yes in step S205), the microcomputer detects the received remote controller temperature and the indoor unit thermistor 211. Based on the intake air temperature and the temperature shift value stored in the storage device of the microcomputer, the temperature deviation E is calculated using the following equation (1) (step S206).
Temperature deviation E = Suction air temperature−Remote control temperature−Temperature shift value (1)

The microcomputer of the indoor unit 2 compares the calculated absolute value of the temperature deviation E with a predetermined value stored in a predetermined memory device of the microcomputer (step 207).
If the absolute value of the temperature deviation E is larger than the specified value (Yes in step S207), the transmission interval for transmitting the remote controller temperature from the remote controller 4 to the indoor unit 2 is determined to be a small value (step S208).
On the other hand, when the absolute value of the temperature deviation E is smaller than the specified value (No in step S207), the transmission interval for transmitting the remote controller temperature from the remote controller 4 to the indoor unit 2 is determined to be a large value (step S209).

  The microcomputer of the indoor unit 2 calculates the next timing based on the determined transmission interval (step S210), and transmits the infrared signal indicating the calculated next timing via the indoor unit light transmitting / receiving unit 380 (step S211). .

The microcomputer of the indoor unit 2 updates the temperature shift value stored in the storage device of the microcomputer using the temperature deviation E calculated using the equation (1) (step S212). Here, K is a weighting coefficient stored in the storage device of the microcomputer. The updated temperature shift value is expressed by the following equation (2).
Post-update temperature shift value = temperature shift value + temperature deviation E × K (2)

After the temperature shift value is updated, the process returns to step S205.
Further, the control of the room temperature of the air conditioner 1 thereafter is performed by referring to the updated temperature shift value, so that the intake air temperature quickly approaches the set temperature obtained by adding the temperature shift value to the set temperature, Air conditioning capacity such as cooling capacity is controlled.

Here, by repeating these controls, the temperature shift value becomes constant in a stable state where the additional set temperature at which the following equation (3) is established is equal to the intake air temperature. The amount (temperature deviation E × K) becomes zero, and the following equation (4) is established.
Additional set temperature (= set temperature + temperature shift value) = intake air temperature (3)
Temperature deviation E = 0 = Suction air temperature−Remote control temperature−Temperature shift value (4)
From these two equations, the following equation (5) is established.
Remote control temperature = set temperature (5)
Thus, the air temperature (remote control temperature) around the remote control 4 placed near the user becomes equal to the set temperature. In other words, the air temperature around the user is air-conditioned without exceeding the set temperature.

In addition, in a stable state where the additional set temperature is equal to the intake air temperature, the temperature shift value is constant, but this constant temperature shift value is the remote control that is the intake air temperature and the temperature of the user's space. It becomes equal to the difference with temperature.
The temperature shift value in the stable state is stored for each operation mode such as heating, cooling and dehumidification of the air conditioner 1 and used as an initial value when starting operation in the same operation mode from the next time onward, thereby starting operation. From the beginning, the operation is performed with a certain temperature shift value with a proven track record, and the set temperature is reached quickly with less fluctuation.

≪Action and effect of air conditioner≫
According to the air conditioner 1 according to the present embodiment, when the remote controller temperature is transmitted from the remote controller 4 to the indoor unit 2, the temperature deviation E is calculated from the intake air temperature, the remote controller temperature, and the current temperature shift value. The temperature shift value is updated using the temperature deviation E. The updated temperature shift value is added to the set temperature, and the operation of the air conditioner 1 is controlled so that the intake air temperature approaches the added set temperature.
In this way, the temperature shift value is updated every time the indoor unit 2 receives the remote controller temperature. By repeating this control, finally, the difference between the intake air temperature and the set temperature becomes equal to the difference between the intake air temperature and the remote control temperature, and the remote control temperature becomes equal to the set temperature. Can fulfill.
Even when there is an interval from reception of the remote control temperature to reception of the next remote control temperature, the operation of the air conditioner 1 can be controlled by the intake air temperature and the set temperature added.

Moreover, according to the air conditioner 1 which concerns on this embodiment, the air temperature around the position of the remote control 4 is air-conditioned to preset temperature. That is, by placing the remote control 4 around the user, the user's surroundings are air-conditioned without excess or deficiency.
For this reason, according to the air conditioner 1 according to the present embodiment, the heating power and / or the cooling power are set so that the temperature around the remote control where the user is located approaches the set temperature without requiring a troublesome operation for the user. A properly controlled air conditioner can be provided.

  In addition, the air conditioner 1 according to the present embodiment determines a transmission interval for transmitting the remote controller temperature detected by the remote control thermistor 411 to the indoor unit 2 according to the intake air temperature, the remote controller temperature, and the temperature shift value. The remote controller temperature is transmitted to the indoor unit 2 in accordance with the determined transmission interval.

  In general, the indoor unit 2 is often installed at a high place in a room, and a wireless remote controller 4 using a built-in battery as a power source is used to operate the air conditioner 1 from a position where a user is present. For this reason, if the built-in battery of the remote control 4 runs out, the air conditioner 1 itself may not be able to operate, and the user needs to replace the built-in battery of the remote control 4 which is troublesome for the user.

The internal battery of the remote controller 4 is consumed most frequently during transmission of information transmitted from the remote controller 4 to the indoor unit 2, and in addition, the remote controller 4 waits because it receives a signal from the indoor unit 2. When using the built-in battery, it is less than when sending, but the internal battery is draining.
For this reason, it is important to reduce the consumption of the internal battery during transmission / reception of the remote controller 4 in order to extend the internal battery of the remote controller 4 and maintain the convenience of the user.

Further, when the air conditioner 1 is controlled using the remote controller temperature, it is necessary to transmit the remote controller temperature from the remote controller 4 to the indoor unit 2 at appropriate intervals, but the difference between the remote controller temperature and the set temperature is large immediately after the start of operation. Because it is necessary to quickly bring the remote control temperature close to the set temperature, the remote control temperature changes in a short time because the room is air conditioned with great capacity.
For this reason, if the remote control temperature transmission interval required for controlling the air conditioner 1 is too long, the room temperature may change beyond the set temperature, and air conditioning may be excessively performed. On the contrary, if the remote control temperature transmission interval is short, the internal battery of the remote control 4 is consumed quickly, and the internal battery needs to be replaced.

According to the air conditioner 1 according to this embodiment, a value obtained by subtracting the remote control temperature and the temperature shift value from the intake air temperature is defined as a temperature deviation E. When the absolute value of the temperature deviation E is large, the remote control temperature is set at a predetermined interval. Send.
Here, the value obtained by subtracting the temperature shift value from the intake air temperature is approximately the set temperature if the temperature shift value is approximately appropriate, and the temperature deviation E is approximately the difference between the set temperature and the remote control temperature.

  When the temperature deviation E is large, the remote controller temperature transmission interval is shortened. When the temperature deviation E is large, the difference between the remote controller temperature and the set temperature is large, and the air conditioner 1 is operated with a large capacity, but the remote controller temperature is transmitted at a relatively short interval. Therefore, the temperature shift value is appropriately updated and the air conditioning capability is adjusted, so that it is possible to prevent excessive air conditioning.

When the temperature deviation E is small, the remote controller temperature transmission interval is lengthened. The temperature deviation E is small when the remote control temperature approaches the set temperature, and the temperature shift value approaches the intake air temperature minus the remote control temperature ≒ the set temperature, in other words, the intake air temperature is the set temperature. The air conditioner 1 is operated with a small capacity.
When the remote control temperature approaches the set temperature, the air conditioning capability is reduced in this way, so the rate of change of the remote control temperature is small, and it is necessary to refer to the remote control temperature frequently in controlling the air conditioner 1. Even if the transmission interval of the remote control temperature is transmitted at a relatively long predetermined time interval, the change in the remote control temperature is small and air conditioning is not excessively performed. Thereby, the consumption of the internal battery of the remote control 4 can be suppressed by reducing the number of transmissions from the remote control 4 toward the indoor unit 2.

  In the air conditioner 1 according to the present embodiment, the transmission interval determined by the absolute value of the temperature deviation E has been described as two stages, but the present invention is not limited to this, and the assumed remote controller temperature and set temperature The number of transmissions from the remote controller 4 is reduced while preventing excessive air conditioning by further changing the transmission interval in multiple stages, such as when the difference between the two is large or the air conditioning capacity is too large compared to the air conditioning load. be able to.

  In the air conditioner 1 according to the present embodiment, the transmission interval is determined according to the intake air temperature, the remote control temperature, and the temperature shift value. However, the transmission interval may be determined according to the set temperature and the remote control temperature. In this case, the same effect as described above can be obtained by setting the temperature deviation E to the difference between the set temperature and the remote controller temperature.

Moreover, the air conditioner 1 which concerns on this embodiment transmits the next timing to the remote control 4 from the indoor unit 2 as transmission interval information.
In general, with the recent increase in energy conservation awareness, the remote controller 4 displays indoor / outdoor temperature / humidity and the operating condition of the air conditioner 1, and the air conditioner 1 is frequently turned on and off according to the circumstances. However, since there is an increasing demand for suppressing the power consumption of the air conditioner 1, the indoor unit 2 has a transmission function to the remote controller 4, and is detected by the indoor unit 2 in response to a request from the remote controller 4. Possible power consumption, outdoor temperature, failure information, operation information, and the like are transmitted to the remote controller 4 and displayed on the LCD 402 of the remote controller 4.

In developing products, various constants are used. However, these constants are rarely found to have appropriate values from the beginning, and appropriate values have been obtained through trial and error during product development. Often sought out.
At this time, as a software development method to be used, these constants are stored in the ROM, and a ROM that can be detachably attached via the ROM socket is mounted on the apparatus, and the above constants are variously changed and examined. To be done.
In this case, if this method is adopted for the remote controller 4, the outer casing of the remote controller 4 becomes larger by the size of the ROM socket, the usability of the remote controller 4 becomes worse, and the manufacturing cost of the remote controller 4 also increases. End up.

The air conditioner 1 according to the present embodiment stores constants such as the above-described weighting coefficient K and a predetermined transmission interval in a ROM as a microcomputer storage device of the indoor unit 2, performs calculations in the indoor unit 2, and results thereof Is transmitted to the remote controller 4.
This eliminates the need for the remote control 4 to include a calculation circuit for calculating the temperature deviation E and a circuit for determining the transmission interval, so that the life of the built-in battery of the remote control 4 can be extended. 4 can be reduced in size.
In addition, it is not necessary to mount a detachable and rewritable ROM on the remote controller 4 in order to study various constants in the course of product development, so that the remote controller 4 can be made compact.

When experience of product development is accumulated so that the examination during the product development for determining constants such as the weighting coefficient K and the predetermined transmission interval described above can be omitted, a rewritable ROM is mounted on the remote controller 4. Since there is no need, the transmission interval may be determined according to the set temperature and the remote control temperature as described above.
At this time, since the data of the indoor unit 2 such as the intake air temperature is not necessary, the transmission interval can be determined by the remote controller 4, and it is only necessary to send the remote controller temperature data to the indoor unit 2 unilaterally. The reception standby time for waiting for transmission of the remote control 4 can be shortened, and consumption of the internal battery of the remote control 4 can be further suppressed.

In the air conditioner 1 according to the present embodiment, the next timing transmission (see step S212 in FIG. 7) as the transmission interval information from the indoor unit 2 is received from the remote controller 4 (see step S205 in FIG. 7). Followed by
As a result, the IR receiver 421 that is a receiving unit of the remote controller 4 is set in a reception standby state only from the transmission of the remote controller temperature (see step 109 in FIG. 6) to the reception of the next timing as the transmission interval information (see step S105 in FIG. 6). In other times, the reception standby state is canceled and the reception is disabled, so that the reception standby state that consumes the power of the built-in battery of the remote control 4 is avoided and the consumption of the internal battery of the remote control 4 is suppressed. be able to.

In addition, the air conditioner 1 according to the present embodiment has a storage device that holds a temperature shift value immediately before the switching of the operation including the operation stop, and the temperature immediately after the switching of the operation including the start of the operation. As the shift value, the temperature shift value of the latest operation that is held in the storage device is used.
As a result, when the operation is switched, including at the start of operation, the operation is performed with the final temperature shift value at the same time in the last past operation. Since the air conditioner 1 is controlled with a highly probable temperature shift value which is the difference between the intake air temperature of the conditioner 1 and the temperature of the place where the remote control 4 is located, it is possible to operate with high control stability, The remote control temperature can be brought close to the set temperature.

In the air conditioner 1 according to the present embodiment, the temperature shift value immediately before the switching of the operation is held in the storage device for each operation mode including at least the heating or cooling operation.
As a result, even if the difference between the intake air temperature and the remote control temperature does not become uniform between heating and cooling due to the natural convection effect caused by the hot and cold air blown out from the air conditioner 1 and the short circuit, In addition, since the operation starts with the latest temperature shift value in the same operation mode, the operation with high control stability is possible, and the remote control temperature can be brought close to the set temperature quickly.
For this reason, the air conditioner 1 which air-conditions the surroundings of the remote control in which a user exists quickly to preset temperature can be provided.

≪Modification≫
Next, a modification of the air conditioner 1 according to the present embodiment will be described.
The air conditioner 1 according to the modification includes a position detection function of the remote controller 4 in addition to the air conditioner 1 according to the present embodiment.

First, the position detection function of the remote controller 4 provided in the air conditioner 1 will be described.
The indoor unit 2 sequentially transmits infrared signals from transmission elements 382, 383, and 384 (see FIG. 3) arranged in three directions, and the remote controller 4 transmits to which the infrared signal from which transmission element is received to the indoor unit 2. To do. Thus, the indoor unit 2 can determine whether the user operating the remote controller 4 is in the right side area, the center area, or the left side area of the room. Further, the indoor unit 2 transmits a signal while changing the intensity of the infrared signal from the transmitting elements 382, 383, and 384, and determines the intensity of the signal that the remote controller 4 has received. A distance (eg, far, middle, near) can be determined.
As described above, the indoor unit transmission / reception unit 380 of the indoor unit 2 and the remote control transmission / reception unit 401 of the remote controller 4 constitute a position detection function of the remote control 4 of the air conditioner 1.

Next, the control of the wind direction of the air conditioner 1 using the position detection function of the remote controller 4 will be described with reference to FIG.
FIG. 8 is a detection area division diagram of the room in which the indoor unit is installed.
The room 902 in which the indoor unit 2 is installed is divided into a left region, a central region, a right region, and detection regions 501 to 509 divided by the distance from the indoor unit 2. In FIG. 9, the detection area is divided into nine detection areas, but the number of detection areas may be changed as appropriate depending on the position detection capability of the remote control 4 of the air conditioner.

Generally, in order to save energy by spot-air-conditioning around the air conditioner user, the temperature is detected at the position of the remote control placed near the user, and the surrounding space where the user is located is comfortable. To be done.
When performing spot-like air conditioning, the up-and-down wind direction plate is directed toward the user near the remote controller 4, that is, the indoor unit 2 blows out the conditioned air toward the detection area where the remote controller 4 is determined to be located. 291 and 292 and the right and left wind direction plates 295 are controlled.

  In contrast to the above, there are users who do not want to directly hit the conditioned air blown out from the indoor unit 2. In order to respond to the needs of such users, in order to avoid users who are near the remote control 4, that is, so as to blow out conditioned air toward the detection area avoiding the detection area where the remote control 4 is determined to be located, At least one of the up / down wind direction plates 291 and 292 and the left / right wind direction plates 295 is controlled.

  For example, spot air conditioning when it is determined that the remote controller 4 is located in the detection area 505 will be described. At least one of the up-and-down wind direction plates 291 and 292 and the left and right wind direction plates 295 is controlled so that the conditioned air blown out from the indoor unit 2 is directed to the detection region 505.

On the other hand, when air conditioning is performed so as to avoid the user, the up / down wind direction plates 291, 292 and the left and right sides of the detection area 504 and the detection area 506 adjacent to the detection area 505 are blown toward one or both of the detection areas 504. At least one of the wind direction plates 295 is controlled.
As a result, it is possible to avoid the direct wind, but it is possible to meet the needs of people who desire gentle air conditioning with the gentle wind around the area.
Therefore, it is possible to obtain an air conditioner that meets the needs for mild air conditioning without directly hitting cold air or hot air.

Further, when the position of the remote controller 4 is detected, the number of rotations of the indoor blower fan 34 may be increased as the position of the remote controller 4 moves away from the indoor unit 2 from the indoor unit 2.
Thereby, when the distance to the remote controller 4 is far, the number of rotations of the indoor fan 34 is increased so that the conditioned air reaches near the place where the remote controller 4 is located. Further, when the distance to the remote controller 4 is short, the number of rotations of the indoor blower fan 34 is decreased to suppress excessive air flow so that the room is not disturbed.
Therefore, it is possible to provide an air conditioner that comfortably air-conditions the space around the remote controller near the user regardless of the position in the room.

Moreover, it is good also as a structure which preserve | saves the temperature shift value preserve | saved at the memory | storage device of the microcomputer of the indoor unit 2 for every detection area | region 501-509.
As a result, even if the user's location is different from the previous time, the direction and distance from the air conditioner 1 are different, and the difference between the intake air temperature and the remote controller temperature is not the same, the same detection area is detected each time the operation is started. Since the operation starts at the most recent temperature shift value, the remote control temperature can be brought close to the set temperature quickly by the operation with high control stability.
For this reason, the air conditioner 1 which air-conditions the surroundings of the remote control 4 in which a user exists quickly to preset temperature can be provided.

1 Air conditioner 2 Indoor unit (air conditioner body)
211 Indoor unit thermistor (suction air temperature sensor)
20 casing 21 casing base 23 decorative frame 25 front panel 251 movable panel 1
27 Air Suction Port 270 Upper Air Suction Portion 270 ′ Front Air Suction Portion 271 Filter 29 Air Blowout Port 290 Blowing Air Path 291 Vertical Air Direction Plate 292 Vertical Air Direction Plate 295 Horizontal Air Direction Plate 33 Indoor Heat Exchanger 34 Indoor Air Fan (Blower)
35 Dew tray 380 Indoor unit transmission / reception unit 381 IR receiver 382 Central transmission element 383 Left transmission element 384 Right transmission element 390 Display device 4 Remote control 401 Remote control transmission / reception unit 402 LCD
403 Operation panel 410 Thermistor ventilation path 411 Remote control thermistor (remote control temperature sensor)
421 IR receiver 422 Transmitting elements 501 to 509 Detection area 6 Outdoor unit 8 Connection pipe 902 Room

Claims (10)

A remote control temperature sensor is provided in the remote controller for inputting the set temperature and operation instructions, and an air intake air temperature sensor is provided in the air conditioner body.
Heating is performed so that the intake air temperature approaches the set temperature obtained by adding a temperature shift value determined according to the remote control temperature detected by the remote control temperature sensor and the intake air temperature detected by the intake air temperature sensor to the set temperature. In an air conditioner that controls power or / and cooling power,
A transmission interval for transmitting the remote control temperature detected by the remote control temperature sensor to the air conditioner body is determined according to the intake air temperature, the remote control temperature, and the temperature shift value, and the remote control is set to the determined transmission interval. In response, the remote controller temperature is transmitted to the main body of the air conditioner. The air conditioner according to claim 1, wherein the transmission interval is determined according to an absolute value of a value obtained by subtracting the remote control temperature and the temperature shift value from the intake air temperature. The air conditioner according to claim 2, wherein the transmission interval is set longer as an absolute value of a value obtained by subtracting the remote control temperature and the temperature shift value from the intake air temperature is smaller. From the transmission interval when the absolute value of the value obtained by subtracting the remote control temperature and the temperature shift value from the intake air temperature is larger than a specified value,
The air conditioner according to claim 3, wherein the transmission interval when the absolute value is equal to or less than the specified value is set long. The air conditioner according to any one of claims 1 to 4, wherein the transmission interval information is transmitted from the air conditioner body to the remote controller. Transmission of the transmission interval information from the air conditioner body,
The air conditioner according to claim 5, wherein the air conditioner is performed following reception of a remote control temperature from the remote control. It further has a function of detecting the position of the remote control,
The air conditioner according to any one of claims 1 to 6, wherein a wind direction and an air volume of the air conditioner are controlled in accordance with a position of the remote controller. The temperature shift value immediately before the switching of the operation of at least two or more of the indoor areas divided by the position detection function of the remote controller is held in the storage device for each area. Air conditioner. The air conditioner according to claim 7, wherein the rotation speed of the blower of the air conditioner main body is greatly changed as the position of the remote controller is further away from the air conditioner main body. The air conditioner according to claim 7, wherein conditioned air is sent to a region adjacent to a region where the remote controller is determined to be located by the detection function of the remote controller.

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