JP6220707B2 - Air conditioner and air conditioning system - Google Patents

Description

  The present invention relates to an air conditioner and an air conditioning system effective for heat shock suppression measures.

  In the past, "a large-scale office building air conditioner that automatically changes the set temperature based on the outside air temperature during cooling operation and suppresses heat shock when entering a building" has been proposed (for example, (See JP 2005-061716).

Japanese Patent Laid-Open No. 2005-061716

  By the way, in recent years, countermeasures for suppressing heat shock have been desired in ordinary homes and small offices. Therefore, it is also conceivable to sell an air conditioner with a heat shock suppression function as described above to ordinary households or small-scale office users. However, since such an air conditioner for an office building does not have a manual setting function, a resident cannot freely change the setting.

  The subject of this invention is providing the air conditioner and air conditioning system which can perform the heat shock suppression measure with respect to residents, such as a house of a general household, and a small office.

An air conditioner according to a first aspect of the present invention includes an air conditioning mechanism, a presence / absence determination unit, an indoor environment information acquisition unit, an outside air environment information acquisition unit , a first information storage unit, and a control unit. Note that the air conditioner referred to here may include not only a temperature-controllable unit but also a humidity-controllable unit. The air conditioning mechanism is not particularly limited, and is, for example, a heat pump air conditioning mechanism including a compression mechanism and an expansion mechanism, a humidity adjustment mechanism, or the like. The presence / absence determination unit determines the presence / absence of an object. The “object” here is, for example, an animal such as a person or a pet. The indoor environment information acquisition unit acquires information on the indoor environment index value. Here, the “room environment index value” includes, for example, room temperature, room humidity, room temperature, room discomfort index, room PMV (Predicted Mean Vote) value, and the like. This indoor environment index value may be a single parameter value or may be composed of a plurality of parameter values. The indoor environment information acquisition unit may acquire the indoor environment index value from the indoor temperature sensor of the indoor unit, or may acquire it from other devices in the room via a network or the like. The outside air environment information acquisition unit acquires information on the outside air environment index value. The “outside air environment index value” here is, for example, the outside air temperature, the outside air humidity, the outdoor body temperature, the outside air discomfort index, the outside air PMV (Predicted Mean Vote) value, or the like. This outdoor air environment index value may be a single parameter value or may be composed of a plurality of parameter values. The outdoor air environment information acquisition unit may acquire an outdoor air environment index value from an outdoor air temperature sensor of the outdoor unit, or may acquire it from a Meteorological Agency server or the like via a network. Information on the first control reference value is stored in the first information storage unit. Control unit executes a first control Te any time odor after the point where the object is determined to be absent by the existence determination unit, it is determined that the object by existence determination unit in the first control in the presence When the difference between the outdoor air environment index value and the indoor environment index value is larger than the first control reference value in the state where the air condition is determined, the second control is executed . Note that the control unit may execute the first control immediately when the presence / absence determination unit determines that the object is absent. In the first control, the control unit controls the air conditioning mechanism so that the indoor environment index value approaches the outside air environment index value. In the second control, the air conditioning mechanism is controlled so that the indoor environment index value is gradually stepped away from the outside air environment index value. The final target value of the indoor environment index value in the second control may be a set value of a controller such as a remote controller before the first control, or may be a predetermined control set value, It may be a value calculated from an outside air environment index value.

An air conditioner according to a second aspect of the present invention includes an air conditioning mechanism, a presence / absence determination unit, an indoor environment information acquisition unit, an outdoor air environment information acquisition unit, an operation mode selection unit, and a control unit. Note that the air conditioner referred to here may include not only a temperature-controllable unit but also a humidity-controllable unit. The air conditioning mechanism is not particularly limited, and is, for example, a heat pump air conditioning mechanism including a compression mechanism and an expansion mechanism, a humidity adjustment mechanism, or the like. The presence / absence determination unit determines the presence / absence of an object. The “object” here is, for example, an animal such as a person or a pet. The indoor environment information acquisition unit acquires information on the indoor environment index value. Here, the “room environment index value” includes, for example, room temperature, room humidity, room temperature, room discomfort index, room PMV (Predicted Mean Vote) value, and the like. This indoor environment index value may be a single parameter value or may be composed of a plurality of parameter values. The indoor environment information acquisition unit may acquire the indoor environment index value from the indoor temperature sensor of the indoor unit, or may acquire it from other devices in the room via a network or the like. The outside air environment information acquisition unit acquires information on the outside air environment index value. The “outside air environment index value” here is, for example, the outside air temperature, the outside air humidity, the outdoor body temperature, the outside air discomfort index, the outside air PMV (Predicted Mean Vote) value, or the like. This outdoor air environment index value may be a single parameter value or may be composed of a plurality of parameter values. The outdoor air environment information acquisition unit may acquire an outdoor air environment index value from an outdoor air temperature sensor of the outdoor unit, or may acquire it from a Meteorological Agency server or the like via a network. An operation mode selection part makes a user (user) select an operation mode. The control unit executes the third control at any time after the time when the specific operation mode is selected by the operation mode selection unit, and when the presence determination unit determines that the target is absent, 4 Control is executed. In the third control, the air conditioning mechanism is controlled so that the indoor environment index value approaches the outside air environment index value. In the fourth control, the air conditioning mechanism is controlled so that the indoor environment index value is closer to the outdoor air environment index value. Here, the “specific operation mode” is, for example, an automatic operation mode, a heat shock suppression countermeasure mode, or the like. The operation mode may be selected in an on / off format or in a candidate selection format.

An air conditioning system according to a third aspect of the present invention includes an air conditioning mechanism, a presence / absence determination unit, an indoor environment information acquisition unit, an outdoor air environment information acquisition unit, an eleventh information storage unit, and a control unit. In addition, this air conditioning system does not need to be accommodated in one housing | casing, The apparatus accommodated in a separate housing | casing may be communicatively connected via the communication line etc. In addition, the air conditioning system referred to here may include a plurality of types of air conditioner mechanisms. The presence / absence determination unit determines the presence / absence of an object. The indoor environment information acquisition unit acquires information on the indoor environment index value. The indoor environment information acquisition unit may acquire information on a plurality of types of indoor environment index values. The outside air environment information acquisition unit acquires information on the outside air environment index value. The outside air environment information acquisition unit may acquire information on a plurality of types of outside air environment index values. The eleventh information storage unit stores information on the eleventh control reference value. Control unit performs Te any time odor after the point where the object is determined to be absent eleventh controlled by existence determination unit, it is determined that the object by existence determination unit in the first 11 control in the presence If the difference between the outdoor air environment index value and the indoor environment index value is larger than the eleventh control reference value in the state where the air condition is met, the twelfth control is executed . Note that the control unit may execute the eleventh control immediately when the presence / absence determination unit determines that the object is absent. In the eleventh control, the control unit controls the air conditioning mechanism so that the indoor environment index value approaches the outside air environment index value. In the twelfth control, the air conditioning mechanism is controlled so that the indoor environment index value is gradually stepped away from the outside air environment index value. The final target value of the indoor environment index value in the twelfth control may be a set value of a controller such as a remote controller before the eleventh control, or may be a predetermined control set value, It may be a value calculated from an outside air environment index value.

An air conditioning system according to a fourth aspect of the present invention includes an air conditioning mechanism, a presence / absence determination unit, an indoor environment information acquisition unit, an outdoor air environment information acquisition unit, an operation mode selection unit, and a control unit. In addition, this air conditioning system does not need to be accommodated in one housing | casing, The apparatus accommodated in a separate housing | casing may be communicatively connected via the communication line etc. In addition, the air conditioning system referred to here may include a plurality of types of air conditioner mechanisms. The presence / absence determination unit determines the presence / absence of an object. The indoor environment information acquisition unit acquires information on the indoor environment index value. The indoor environment information acquisition unit may acquire information on a plurality of types of indoor environment index values. The outside air environment information acquisition unit acquires information on the outside air environment index value. The outside air environment information acquisition unit may acquire information on a plurality of types of outside air environment index values. An operation mode selection part makes a user (user) select an operation mode. The control unit executes the thirteenth control at any time after the time when the specific operation mode is selected by the operation mode selection unit, and when the presence determination unit determines that the target is absent, 14 Control is executed. In the thirteenth control, the air conditioning mechanism is controlled so that the indoor environment index value approaches the outside air environment index value. In the fourteenth control, the air conditioning mechanism is controlled so that the indoor environment index value is closer to the outdoor air environment index value. Here, the “specific operation mode” is, for example, an automatic operation mode, a heat shock suppression countermeasure mode, or the like. The operation mode may be selected in an on / off format or in a candidate selection format.

  In the air conditioner according to the present invention, as described above, the control unit executes the first control, that is, the heat shock suppression control at any time after the time when the presence determination unit determines that the object is absent. . That is, heat shock suppression measures are taken when a person or the like goes out. For this reason, this air conditioner can perform heat shock suppression measures for residents such as ordinary households and small offices.

It is a schematic block diagram of the air conditioner concerning 1st Embodiment. In this figure, the four-way switching valve is in the cooling operation state. It is a schematic block diagram of the air conditioner concerning 1st Embodiment. In this figure, the four-way switching valve is in the heating operation state. It is a block diagram showing the hardware constitutions of the air conditioner concerning a 1st embodiment. It is a flowchart which shows the heat shock suppression control of the air conditioner concerning 1st Embodiment. It is a time-temperature relationship figure in case the heat shock suppression control is performed in the air conditioner concerning 1st Embodiment. It is a time-temperature relationship figure in case the heat shock suppression control is not performed in the air conditioner concerning 1st Embodiment. It is a flowchart which shows the heat shock suppression control of the air conditioner concerning 2nd Embodiment. It is a flowchart which shows the heat shock suppression control of the air conditioner concerning 3rd Embodiment. It is a time-temperature relationship figure in case the heat shock suppression control is performed in the air conditioner concerning 3rd Embodiment. It is a time-temperature relationship figure in case the heat shock suppression control is not performed in the air conditioner concerning 3rd Embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following description, the same parts are denoted by the same reference numerals. Their names and functions are also the same. Therefore, detailed description thereof will not be repeated.

-First embodiment-
<Overall configuration and operation of air conditioner>

  First, the overall configuration and basic operation outline of the air conditioner 1 according to the present embodiment will be described.

The air conditioner 1 according to the present embodiment is a separate type air conditioner, and mainly includes an outdoor unit 10, an indoor unit 30, and a remote controller 50 ( operation mode selection unit) as shown in FIG. It is composed of As shown in FIG. 1, the air conditioner 1 is configured by connecting an indoor unit 30 and an outdoor unit 10 via a liquid side communication pipe 41 and a gas side communication pipe 42. Hereinafter, the outdoor unit 10, the indoor unit 30, the remote controller 50, the liquid side communication pipe 41, and the gas side communication pipe 42 will be described in detail.

(1) Outdoor unit As shown in FIG. 1, the outdoor unit 10 mainly includes a housing 11, a compressor 12, a four-way switching valve 13, an outdoor heat exchanger 14, an expansion valve 15, and an outdoor blower 16. , Liquid side refrigerant pipe 17, gas side refrigerant pipe 18, two-way valve 19, three-way valve 20, outdoor heat exchanger temperature detector 21, discharge temperature detector 22, suction temperature detector 23, expansion valve vicinity temperature detector 24, an outside air temperature detector 25 (outside air environment information acquisition unit) and an outdoor side controller 29. The outdoor unit 10 is installed outdoors.

  As shown in FIG. 1, the casing 11 includes a compressor 12, a four-way switching valve 13, an outdoor heat exchanger 14, an expansion valve 15, an outdoor blower 16, a liquid side refrigerant pipe 17, and a gas side refrigerant pipe. 18, two-way valve 19, three-way valve 20, temperature detectors 21 to 25, outdoor controller 29, and the like are housed.

  As shown in FIG. 1, the compressor 12 has a discharge pipe 12a and a suction pipe 12b. The discharge pipe 12a and the suction pipe 12b are connected to different connection ports of the four-way switching valve 13, respectively. The compressor 12 is communicatively connected to the outdoor controller 29 via a communication line, and operates according to a control signal transmitted from the outdoor controller 29. During operation, the compressor 12 sucks low-pressure refrigerant gas from the suction pipe 12b, compresses the refrigerant gas to generate high-pressure refrigerant gas, and then discharges the high-pressure refrigerant gas from the discharge pipe 12a. In the present embodiment, the control format of the compressor 12 is not particularly limited, and may be a constant speed compressor or an inverter compressor.

  As shown in FIG. 1, the four-way switching valve 13 is connected to the discharge pipe 12 a and the suction pipe 12 b of the compressor 12, the outdoor heat exchanger 14, and the indoor heat exchanger 32 through a refrigerant pipe. . The four-way switching valve 13 is communicatively connected to the outdoor controller 29 via a communication line, and operates according to a control signal transmitted from the outdoor controller 29. The four-way switching valve 13 connects the discharge pipe 12a of the outdoor controller compressor 12 to the outdoor heat exchanger 14 and sucks the compressor 12 in accordance with a control signal transmitted from the outdoor controller 29 during operation. The cooling operation state (see FIG. 1) in which the pipe 12b is connected to the indoor heat exchanger 32, the discharge pipe 12a of the outdoor controller compressor 12 is connected to the indoor heat exchanger 32, and the suction pipe of the compressor 12 It switches to the heating operation state (refer FIG. 2) which connects 12b to the outdoor side heat exchanger 14. FIG.

  The outdoor heat exchanger 14 has a large number of radiating fins (not shown) attached to a heat transfer tube (not shown) bent back and forth at both left and right ends, and during cooling operation (see FIG. 1). Functions as a condenser, and functions as an evaporator during heating operation (see FIG. 2).

  The expansion valve 15 is an electronic expansion valve whose opening degree can be controlled. The expansion valve 15 is connected to the two-way valve 19 via the liquid side refrigerant pipe 17 and is connected to the outdoor heat exchanger via the other liquid side refrigerant pipe. 14. The expansion valve 15 is communicatively connected to the outdoor controller 29 via a communication line, and operates according to a control signal transmitted from the outdoor controller 29. The expansion valve 15 is in a state in which the high-temperature and high-pressure liquid refrigerant flowing out from the condenser (the outdoor heat exchanger 14 during cooling and the indoor heat exchanger 32 during heating) is easily evaporated during operation. While decompressing, it plays the role of adjusting the amount of refrigerant supplied to the evaporator (the indoor heat exchanger 32 during cooling and the outdoor heat exchanger 14 during heating).

  The outdoor blower 16 is mainly composed of a propeller fan and a motor. The propeller fan is rotationally driven by a motor, and supplies outdoor outdoor air to the outdoor heat exchanger 14. As shown in FIG. 1, the motor is communicatively connected to the outdoor controller 29 via a communication line, and operates according to a control signal transmitted from the outdoor controller 29.

  As shown in FIG. 1, the liquid side refrigerant pipe 17 is a pipe extending from the expansion valve 15 toward the two-way valve 19. As shown in FIG. 1, the gas-side refrigerant pipe 18 is a pipe extending from the four-way switching valve 13 toward the three-way valve 20.

  As shown in FIG. 1, the two-way valve 19 is disposed at the end of the liquid side refrigerant pipe 17. As shown in FIG. 1, a liquid side communication pipe 41 is connected to the two-way valve 19. The two-way valve 19 is closed when the liquid side connection pipe 41 is removed from the outdoor unit 10 to prevent the refrigerant from leaking from the outdoor unit 10 to the outside.

  As shown in FIG. 1, the three-way valve 20 is disposed at the end of the gas side refrigerant pipe 18. As shown in FIG. 1, a gas side communication pipe 42 is connected to the three-way valve 20. The three-way valve 20 is closed when the gas side communication pipe 42 is removed from the outdoor unit 10 to prevent the refrigerant from leaking from the outdoor unit 10 to the outside. Further, when it is necessary to recover the refrigerant from the outdoor unit 10 or from the entire refrigeration cycle including the indoor unit 30, the refrigerant is recovered through the three-way valve 20.

  The temperature detectors 21 to 25 are thermistors. The outdoor heat exchanger temperature detector 21 is disposed in the outdoor heat exchanger 14, the discharge temperature detector 22 is disposed in the discharge pipe 12 a of the compressor 12, and the suction temperature detector 23 is disposed in the compressor 12. The expansion valve vicinity temperature detector 24 is disposed in the refrigerant pipe between the expansion valve 15 and the two-way valve 19, and the outside air temperature detector 25 is for measuring the outside air temperature. Are disposed at predetermined locations inside the housing 11. As shown in FIG. 1, these temperature detectors 21 to 25 are all communicably connected to the outdoor controller 29 via communication lines, and send measured temperature information to the outdoor controller 29. Yes.

  As shown in FIG. 3, the outdoor controller 29 mainly includes a central processing unit 29b, a storage unit 29a (first information storage unit, second information storage unit, third information storage unit, fourth information storage unit). Part), a timer 29d (time measuring part) and a communication part 29c. These components 29a to 29d are connected to each other by a bus. Moreover, the outdoor side controller 29 is connected to the compressor 12, the four-way switching valve 13, the expansion valve 15, the outdoor side fan 16, and the temperature detectors 21 to 25 through a communication line as shown in FIG. ing. The central processing calculation unit 29b derives appropriate control parameters by calculating the output information of the temperature detectors 21 to 25, various control parameters stored in the storage unit 29a, and the like as needed. The data is transmitted to the compressor 12, the four-way switching valve 13, the expansion valve 15, and the outdoor blower 16 through the communication unit 29c. Further, the central processing calculation unit 29b transmits and receives control parameters and the like to the indoor controller 35 via the communication unit 29c as necessary. Control parameters and the like are stored in the storage unit 29a. In addition, the storage unit 29a may store control parameters and the like transmitted from the central processing calculation unit 29b in accordance with instructions from the central processing calculation unit 29b. The timer 29d measures time according to a command from the central processing arithmetic unit 29b, and transmits the measurement signal to the central processing arithmetic unit 29b and the storage unit 29a. The timer 29d may be a software timer. The outdoor controller 29 is communicably connected to the indoor controller 35 via the communication units 29c and 35c, and can be said to constitute one control unit 60 together with the indoor controller 35.

(2) Indoor unit As shown in FIG. 1, the indoor unit 30 mainly includes a casing 31, an indoor heat exchanger 32, an indoor fan 33, a flap 36, an indoor heat exchanger temperature detector 34, An indoor temperature detector 37 (indoor environment information acquisition unit) and an indoor controller 35 are included. The indoor unit 30 is installed indoors.

  As shown in FIG. 1, the housing 31 houses an indoor heat exchanger 32, an indoor fan 33, an indoor heat exchanger temperature detector 34, an indoor temperature detector 37, an indoor controller 35, and the like. Has been. Further, the flap 36 constitutes a part of the housing 31.

  As shown in FIG. 1, the indoor heat exchanger 32 is a combination of three heat exchangers 32 </ b> A, 32 </ b> B, and 32 </ b> C like a roof that covers the indoor blower 33. Each of the heat exchangers 32A, 32B, and 32C has a plurality of radiating fins (not shown) attached to a heat transfer tube (not shown) that is bent back and forth at both left and right ends. It functions as an evaporator (see FIG. 1), and functions as a condenser during heating operation (see FIG. 2).

  The indoor blower 33 is mainly composed of a cross flow fan and a motor. The cross flow fan is rotationally driven by a motor, sucks indoor air into the casing 31 and supplies the air to the indoor heat exchanger 32, and sends the air exchanged by the indoor heat exchanger 32 into the room. As shown in FIG. 1, the motor is communicatively connected to the indoor controller 35 via a communication line, and operates according to a control signal transmitted from the indoor controller 35.

  The flap 36 includes a wind direction plate and a motor. The flap is rotated by a motor and adjusts the sending direction of the air sent into the room by the cross flow fan. As shown in FIG. 1, the motor is communicatively connected to the indoor controller 35 via a communication line, and operates according to a control signal transmitted from the indoor controller 35.

  The temperature detectors 34 and 37 are thermistors. The indoor side heat exchanger temperature detector 34 is disposed in the indoor side heat exchanger 32, and the indoor temperature detector 37 is for measuring the indoor temperature and is disposed in the vicinity of the suction port in the housing. As shown in FIG. 1, the temperature detectors 34 and 37 are communicatively connected to an indoor controller 35 via a communication line, and transmit measured temperature information to the indoor controller 35.

  As shown in FIGS. 1 and 3, the indoor controller 35 mainly includes a central processing calculation unit 35b, an infrared light receiving unit 35a, a communication unit 35c, and a human detection unit 35d. These components 35a to 35d are connected to each other by a bus. Further, as shown in FIG. 1, the indoor controller 35 is communicatively connected to the indoor blower 33, the flap 36, and the temperature detectors 34 and 37 via a communication line. The central processing calculation unit 35b calculates the control signal from the remote controller 50, the output information of the temperature detectors 34, 37, and the like as needed to derive appropriate control parameters, and transmits the control parameters to the communication unit 35c. To the indoor blower 33 and the flap 36. Further, the central processing calculation unit 35b transmits and receives control parameters and the like to the outdoor controller 29 via the communication unit 35c as necessary. The infrared light receiving unit 35a receives flashing infrared light generated from the remote controller 50. The infrared light receiving unit 35a converts the flashing infrared signal into a signal, and transmits the generated signal to the central processing unit 35b. The human detection unit 35d is, for example, various cameras, infrared sensors, or the like, and detects the presence or absence of a person in the space near the indoor unit 30.

  As shown in FIG. 1, the compressor 12, the four-way switching valve 13, the outdoor heat exchanger 14 and the expansion valve 15 of the outdoor unit 10, and the indoor heat exchanger 32 of the indoor unit 30 are refrigerant piping. Are sequentially connected to form a refrigerant circuit. In the present embodiment, the refrigerant circuit, the outdoor blower 16, the indoor blower 33, and the flap 36 are collectively referred to as an air conditioning mechanism, and denoted by reference numeral 2 in FIGS.

(3) Remote controller The remote controller 50 is for transmitting a user command to the indoor controller 35 of the indoor unit 30 using blinking infrared rays, and mainly includes an infrared light emitting unit, a display panel, and an operation. A stop button, a mode switching button, a temperature increase button, a temperature decrease button, an air volume increase button, an air volume decrease button, an air direction adjustment button, an automatic operation button, and the like are included.

  The display panel displays information such as set temperature, wind direction, air volume, and operation mode. For this reason, the user can confirm the present driving | running state of the air conditioner 1 by confirming a display panel.

  When the operation stop button is pressed by the user during operation, the infrared light emitting unit emits infrared light having a blinking pattern that stops the air conditioner 1 and when pressed by the user during the stop, the infrared light emitting unit. On the other hand, the infrared ray of the blink pattern which drives the air conditioner 1 is light-emitted.

  Each time the mode switching button is pressed by the user during operation, the infrared light emitting unit sequentially operates the infrared light of the blinking pattern for operating the air conditioner 1 in the cooling mode, and the air conditioner 1 is operated in the dehumidifying mode. Infrared light of a blinking pattern, infrared light of a blinking pattern that operates the air conditioner 1 in the heating mode, and infrared light of a blinking pattern that operates the air conditioner 1 in the air blowing mode are emitted. In the air conditioner 1, the control pattern of each operation mode is stored in advance in the storage unit 29 a of the outdoor controller 29.

  Each time the temperature increase button is pressed by the user, the infrared light emitting unit emits a flashing pattern of infrared light that raises the set temperature by 1 ° C. Further, each time the temperature lowering button is pressed by the user, the infrared light emitting unit emits a flashing pattern of infrared light that lowers the set temperature by 1 ° C.

  Each time the air volume increasing button is pressed by the user, the infrared light emitting unit is caused to emit infrared light having a blinking pattern that increases the air volume to a level one level higher. Each time the air volume lowering button is pressed by the user, the infrared light emitting unit causes the infrared light emitting unit to emit infrared light having a blinking pattern that lowers the air volume to a lower level.

  Each time the wind direction adjustment button is pressed by the user, the infrared light emitting unit emits infrared light having a blinking pattern that moves the wind direction plate upward stepwise. When the wind direction adjusting button is pressed by the user when the wind direction plate is positioned at the highest position, the infrared light emitting unit emits infrared light of a blinking pattern that moves the wind direction plate to the lowest position.

  When the automatic operation button is pressed by the user, the infrared light emitting unit emits infrared light having a blinking pattern that automatically operates the air conditioner 1.

(4) Liquid side communication pipe The liquid side communication pipe 17 is a pipe thinner than the gas side communication pipe 18, and liquid refrigerant flows through the liquid side communication pipe 17 during operation. As the refrigerant, for example, HFC type R410A or R32 is used.

(5) Gas side communication pipe The gas side connection pipe 18 is thicker than the liquid side connection pipe 17, and gas refrigerant flows through the gas side connection pipe 18 during operation.

<Basic operation of the air conditioner>
Hereinafter, the cooling operation and the heating operation of the air conditioner 1 according to the present embodiment will be described in detail.

(1) Cooling operation In the cooling operation, the four-way switching valve 13 is in the state shown in FIG. 1, that is, the discharge pipe 12 a of the compressor 12 is connected to the outdoor heat exchanger 14 and the suction pipe of the compressor 12 is used. 12b is connected to the indoor heat exchanger 32. At this time, the two-way valve 19 and the three-way valve 20 are open. When the compressor 12 is started in this state, the gas refrigerant is sucked into the compressor 12 and compressed, and then sent to the outdoor heat exchanger 14 via the four-way switching valve 13, It is cooled in the heat exchanger 14 and becomes a liquid refrigerant. Thereafter, the liquid refrigerant is sent to the expansion valve 15 and is decompressed to be in a gas-liquid two-phase state. The gas-liquid two-phase refrigerant is supplied to the indoor heat exchanger 32 via the two-way valve 19 to cool the indoor air and evaporate into a gas refrigerant. Finally, the gas refrigerant is sucked into the compressor 12 again via the three-way valve 20 and the four-way switching valve 13.

(2) Heating operation In the heating operation, the four-way switching valve 13 is in the state shown in FIG. 2, that is, the discharge pipe 12a of the compressor 12 is connected to the indoor heat exchanger 32, and the suction pipe of the compressor 12 is used. 12b is connected to the outdoor heat exchanger 14. At this time, the two-way valve 19 and the three-way valve 20 are open. When the compressor 12 is started in this state, the gas refrigerant is sucked into the compressor 12 and compressed, and then supplied to the indoor heat exchanger 32 via the four-way switching valve 13 and the three-way valve 20. The indoor air is heated and condensed to become a liquid refrigerant. Thereafter, the liquid refrigerant is sent to the expansion valve 15 via the three-way valve 19 and is decompressed to be in a gas-liquid two-phase state. The gas-liquid two-phase refrigerant is sent to the outdoor heat exchanger 14 and evaporated in the outdoor heat exchanger 14 to become a gas refrigerant. Finally, the gas refrigerant is sucked into the compressor 12 again via the four-way switching valve 13.

<Heat shock suppression control>
In the air conditioner 1 according to the present embodiment, heat shock suppression control is executed when the presence of a person is no longer detected by the person detection unit 35d during operation. Hereinafter, this heat shock suppression control will be described in detail with reference to FIG.

  In FIG. 4, first, in step S101, the central processing unit 29b determines whether or not a person non-detection signal is received from the person detection unit 35d in the communication unit 29c. Here, when the central processing calculation unit 29b determines that the communication unit 29c has received a human non-detection signal from the human detection unit 35d, the central processing calculation unit 29b proceeds to the process of step S102. On the other hand, when the central processing calculation unit 29b determines that the communication unit 29c has not received a human non-detection signal from the human detection unit 35d (that is, the central processing calculation unit 29b receives from the human detection unit 35d in the communication unit 29c). If it is determined that a person detection signal has been received), the central processing unit 29b ends the process. Note that after the end of this process, the central processing unit 29b executes the process of step S101 again after a predetermined time has elapsed.

  In step S102, the central processing unit 29b reads out information on the operation mode at that time from the storage unit 29a, and determines whether or not the operation mode is the cooling mode. Here, when the central processing calculation unit 29b determines that the operation mode is the cooling mode, the central processing calculation unit 29b proceeds to the process of step S103. On the other hand, when the central processing calculation unit 29b determines that the operation mode is not the cooling mode, the central processing calculation unit 29b proceeds to the process of step S111.

  In step S103, the central processing unit 29b reads out the information on the cooling heat shock suppression temperature Tc1 from the storage unit 29a, and sets the indoor set temperature Ts to the cooling cooling heat shock temperature Tc1 (Note that This process corresponds to a setting change from the user set temperature Tu at the time t1 in FIG. 5 to the entrance-time cooling heat shock suppression temperature Tc1. At this time, the central processing unit 29b stores the user set temperature Tu at that time in the storage unit 29a.

  In step S104, the central processing unit 29b determines whether or not a human detection signal is received from the human detection unit 35d in the communication unit 29c. Here, when the central processing calculation unit 29b determines that the communication unit 29c has received a human detection signal from the human detection unit 35d, the central processing calculation unit 29b proceeds to the process of step S105. On the other hand, when the central processing unit 29b determines that the communication unit 29c has not received a human detection signal from the human detection unit 35d, that is, the communication unit 29c has determined that a human non-detection signal has been received from the human detection unit 35d. In this case, the central processing calculation unit 29b returns to the process of step S104.

  In step S105, the central processing unit 29b receives the information of the outdoor temperature To and the indoor temperature Ti (indoor environment index value) at that time from the outdoor temperature detector 25 and the indoor temperature detector 37, respectively, and from the storage unit 29a. After reading the information of the first reference temperature difference ΔTr1 (fourth control reference value), the value obtained by subtracting the indoor temperature Ti (which may be the heat shock suppression temperature Tc1 during cooling for entry) from the outside air temperature To is the first value. It is determined whether or not it is larger than one reference temperature difference ΔTr1. Here, when the central processing calculation unit 29b determines that the value obtained by subtracting the room temperature Ti from the outside air temperature To (outside air environment index value) is larger than the first reference temperature difference ΔTr1, the central processing calculation unit 29b The process proceeds to S106. On the other hand, when the central processing calculation unit 29b determines that the value obtained by subtracting the room temperature Ti from the outside air temperature To is equal to or less than the first reference temperature difference ΔTr1, the central processing calculation unit 29b proceeds to the process of step S107.

  In step S106, the central processing unit 29b reads out the information on the cooling intermediate temperature Tc2 and the user set temperature Tu stored in the storage unit 29a in step 103 from the storage unit 29a, and sets the room set temperature Ts in the entrance cooling mode. The setting is changed stepwise from the heat shock suppression temperature Tc1 to the user set temperature Tu (<Tc2) through the cooling intermediate temperature Tc2 (<Tc1) (this processing is performed during room cooling after time t2 in FIG. 5). This corresponds to a stepwise change in the indoor set temperature Ts (see the solid line portion) from the heat shock suppression temperature Tc1 to the user set temperature Tu via the cooling intermediate temperature Tc2, and is shown in FIG. The indoor setting when it is assumed that the person does not change the indoor set temperature Ts in the state where the person is continuously detected by the person detecting unit 35d. Time course in degrees Ts is shown. In this case, of course, the indoor set temperature Ts, as in FIG. 6, remains the user set temperature Tu.). At this time, the central processing unit 29b expands the compressor 12 and the expansion unit via the communication unit 29c so that the output value of the room temperature detector 37 approaches the room set temperature Ts so that the room temperature becomes the room set temperature Ts. A control signal is transmitted to the machine 15 or the like.

  In step S107, the central processing unit 29b reads the information of the user set temperature Tu stored in the storage unit 29a in step 103 from the storage unit 29a, and sets the indoor set temperature Ts from the entrance cooling heat shock suppression temperature Tc1. The setting is changed to the user set temperature Tu (<Tc1) (Note that this processing changes the indoor set temperature Ts from the entry cooling air-warming heat shock suppression temperature Tc1 to the user set temperature Tu at time t2 ′ in FIG. 5 (one point). This corresponds to the short chain line part). At this time, the central processing unit 29b expands the compressor 12 and the expansion unit via the communication unit 29c so that the output value of the room temperature detector 37 approaches the room set temperature Ts so that the room temperature becomes the room set temperature Ts. A control signal is transmitted to the machine 15, the outdoor fan 16, and the like.

  In step S111, the central processing unit 29b reads out information on the operation mode at that time from the storage unit 29a, and determines whether or not the operation mode is the heating mode. Here, when the central processing calculation unit 29b determines that the operation mode is the heating mode, the central processing calculation unit 29b proceeds to the process of step S112. On the other hand, when the central processing calculation unit 29b determines that the operation mode is not the heating mode, the central processing calculation unit 29b ends the processing. Note that after the end of this process, the central processing unit 29b executes the process of step S101 again after a predetermined time has elapsed.

  In step S112, the central processing unit 29b reads information on the heat shock suppression temperature Tw1 for heating for entry / exit from the storage unit 29a, and sets the indoor set temperature Ts for the heat shock suppression temperature Tw1 for heating for entry / exit. At this time, the central processing unit 29b stores the user set temperature Tu at that time in the storage unit 29a.

  In step S113, the central processing unit 29b determines whether a human detection signal is received from the human detection unit 35d in the communication unit 29c. Here, when the central processing calculation unit 29b determines that the communication unit 29c has received a human detection signal from the human detection unit 35d, the central processing calculation unit 29b proceeds to the process of step S114. On the other hand, when the central processing unit 29b determines that the communication unit 29c has not received a human detection signal from the human detection unit 35d, that is, the communication unit 29c has determined that a human non-detection signal has been received from the human detection unit 35d. In this case, the central processing calculation unit 29b returns to the process of step S113.

  In step S114, the central processing unit 29b receives the outdoor temperature To and the indoor temperature Ti at that time from the outdoor temperature detector 25 and the indoor temperature detector 37, respectively, and at the same time, receives the second reference temperature difference ΔTr2 (first) from the storage unit 29a. (4 control reference value) is read out, and it is determined whether or not the value obtained by subtracting the outside air temperature To from the room temperature Ti (which may be the heat shock suppression temperature Tw1 during room heating) is greater than the second reference temperature difference ΔTr2. To do. Here, when the central processing calculation unit 29b determines that the value obtained by subtracting the outside air temperature To from the room temperature Ti is larger than the second reference temperature difference ΔTr2, the central processing calculation unit 29b proceeds to the process of step S115. On the other hand, when the central processing calculation unit 29b determines that the value obtained by subtracting the outside air temperature To from the room temperature Ti is equal to or smaller than the second reference temperature difference ΔTr2, the central processing calculation unit 29b proceeds to the process of step S116.

In step S115 , the central processing unit 29b reads the information of the user set temperature Tu stored in the storage unit 29a in step 112 from the storage unit 29a, and uses the indoor set temperature Ts from the heat shock suppression temperature Tw1 for heating for entry and exit. The setting is changed to the user set temperature Tu (> Tw1). At this time, the central processing unit 29b expands the compressor 12 and the expansion unit via the communication unit 29c so that the output value of the room temperature detector 37 approaches the room set temperature Ts so that the room temperature becomes the room set temperature Ts. A control signal is transmitted to the machine 15 or the like.

In step S116 , the central processing unit 29b reads out the information on the heating intermediate temperature Tw2 and the user set temperature Tu stored in the storage unit 29a in step 112 from the storage unit 29a, and uses the indoor set temperature Ts as input / output heating time. The setting is changed stepwise from the heat shock suppression temperature Tw1 to the user set temperature Tu (> Tw2) via the heating intermediate temperature Tw2 (> Tw1). At this time, the central processing unit 29b expands the compressor 12 and the expansion unit via the communication unit 29c so that the output value of the room temperature detector 37 approaches the room set temperature Ts so that the room temperature becomes the room set temperature Ts. A control signal is transmitted to the machine 15 or the like.

  After step S103 or step S112 is executed, the air volume is decreased until a person is detected by the person detection unit 35 in step S104 or step S113, and a person is detected by the person detection unit 35 in step S104 or step S113. The air volume may be increased later. In addition, after step S103 or step S112 is executed, until a person is detected by the human detection unit 35 in step S104 or step S113, cold air or hot air may be blown toward the wall or ceiling. Then, even after the person is detected by the person detection unit 35 in step S104 or step S113, the cool air or the warm air is blown toward the wall or ceiling so that the warm air or the cool air is not directly applied to the person. It may be.

<Characteristics of the air conditioner according to the first embodiment>
(1)
In the air conditioner 1 according to the present embodiment, when it is determined that the person is present by the person detection unit 35d, the setting of the room temperature or the like is entrusted to the user, and the person detection unit 35d indicates that no person is present. When it is determined, the central processing calculation unit 29b executes heat shock suppression control. For this reason, this air conditioner 1 can perform heat shock suppression measures without giving stress to residents such as ordinary households and small offices.

(2)
In the air conditioner 1 according to the present embodiment, when the person detection unit 35d determines that a person is present during the heat shock suppression control, the value obtained by subtracting the room temperature Ti from the outside air temperature To is the first reference. When the temperature difference ΔTr1 is greater (cooling operation), the central processing calculation unit 29b changes the indoor set temperature Ts from the entrance cooling heat shock suppression temperature Tc1 to the user set temperature Tu through the cooling intermediate temperature Tc2. Change the setting to. Further, in the air conditioner 1, when it is determined by the human detection unit 35d that the person is present during the heat shock suppression control, the value obtained by subtracting the outside air temperature To from the room temperature Ti is the second reference temperature difference ΔTr2. When the temperature is greater than (heating operation), the central processing unit 29b changes the indoor set temperature Ts from the input / output heating heat shock suppression temperature Tw1 through the heating intermediate temperature Tw2 to the user set temperature Tu in stages. To do. For this reason, in this air conditioner 1, when the difference between the room temperature and the outside air temperature To is significant, a person can gradually get used to the body. Therefore, in this air conditioner 1, the heat shock at the time of entering a room is suppressed.

-Second Embodiment-
The air conditioner according to the second embodiment is different from the air conditioner 1 according to the first embodiment in the aspect of heat shock suppression control. For this reason, about the air conditioner concerning this Embodiment, only heat shock suppression control is demonstrated.

<Heat shock suppression control>
In FIG. 7, the process of the central processing calculation unit 29b in steps S101 to 107 is the same process as steps S101 to 107 in the flowchart (FIG. 4) showing the heat shock suppression control according to the first embodiment. For this reason, the detailed description about these processes is abbreviate | omitted.

  In FIG. 7, the flow from step S111 to step END is omitted, but the flow after step S111 is the same as the flow from step S121 to step END in FIG. . However, in this flow, “To-Ti> ΔTr1?” In step S105 is replaced with “Ti-To> ΔTr2?”, And “Tc1” and “Tc2” in the other steps are changed to “Tw1” and “Tw2”, respectively. Replaced. In such a case, the relationship of Tw1 <Tw2 is established.

  In step S121, the central processing calculation unit 29b operates the timer 29d to start time measurement.

  In step S122, the central processing unit 29b receives the count time (elapsed time) information from the timer 29d, reads the first reference time ts1 (third control reference value) from the storage unit 29a, and the count time t is the first time. It is determined whether or not one reference time ts1 has been reached. Here, when the central processing calculation unit 29b determines that the count time t has reached the first reference time ts1, the central processing calculation unit 29b proceeds to the process of step S103. On the other hand, when the central processing calculation unit 29b determines that the count time t has not reached the first reference time ts1, the central processing calculation unit 29b returns to the process of step S122.

  In step S123, after the central processing unit 29b receives the count time information from the timer 29d and reads the second reference time ts2 (the 31st control reference value) from the storage unit 29a, the count time t becomes the second reference time. It is determined whether or not ts2 (> ts1) has been reached. Here, when the central processing calculation unit 29b determines that the count time t has reached the second reference time ts2, the central processing calculation unit 29b proceeds to the process of step S124. On the other hand, when the central processing calculation unit 29b determines that the count time t has not reached the second reference time ts2, the central processing calculation unit 29b returns to the process of step S104.

  In step S124, the central processing unit 29b causes the compressor 12, the four-way switching valve 13, the expander 15, the outdoor blower 16, and the indoor blower via the communication unit 29c to stop the air conditioner 1. 34, the control signal is transmitted to the flap 36 and the like.

<Characteristics of the air conditioner according to the second embodiment>
(1)
In the air conditioner according to the present embodiment, the central processing unit 29b executes the heat shock suppression control after the first reference time ts1 has elapsed from the time when the human detection unit 35d determines that a person is present. . For this reason, in this air conditioner 1, if the absence period is short, the heat shock suppression control is not executed, and an air-conditioned space that is comfortable for the user can be maintained.

(2)
In the air conditioner according to the present embodiment, the central processing unit 29b stops the air conditioner 1 after the second reference time ts2 has elapsed from the time when the person detecting unit 35d determines that a person is present. And For this reason, this air conditioner 1 can contribute to energy saving.

-Third embodiment-
The air conditioner according to the third embodiment is different from the air conditioner 1 according to the first embodiment in the aspect of heat shock suppression control. For this reason, about the air conditioner concerning this Embodiment, only heat shock suppression control is demonstrated.

<Heat shock suppression control>
When the automatic operation button of the remote controller 50 is pressed by the user, the air conditioner enters the automatic operation mode, and the central processing calculation unit 29b executes the process of step S131 in FIG. Here, the time when the air conditioner is set to the automatic operation mode is represented as ta (see FIG. 9).

  In step S131, the central processing calculation unit 29b operates the timer 29d to start time measurement.

  In step S132, the central processing unit 29b reads out information on the current operation mode from the storage unit 29a, and determines whether or not the operation mode is the cooling mode. Here, when the central processing calculation unit 29b determines that the operation mode is the cooling mode, the central processing calculation unit 29b proceeds to the process of step S133. On the other hand, when the central processing calculation unit 29b determines that the operation mode is not the cooling mode, the central processing calculation unit 29b proceeds to the process of step S151.

  In step S133, the central processing calculation unit 29b reads the information of the automatic operation set temperature Tc0 from the storage unit 29a, and sets the indoor set temperature Ts to the automatic operation set temperature Tc0 (Note that this process is the time of FIG. 9). This corresponds to a setting change from the user set temperature Tu to the automatic operation set temperature Tc0 at ta).

  In step S134, after the central processing unit 29b receives the information of the count time t from the timer 29d and reads the information of the third reference time ts3 from the storage unit 29a, the count time t reaches the third reference time ts3. Determine whether or not. Here, when the central processing calculation unit 29b determines that the count time t has reached the third reference time ts3, the central processing calculation unit 29b proceeds to the process of step S135. On the other hand, when the central processing calculation unit 29b determines that the count time t has not reached the third reference time ts3, the central processing calculation unit 29b returns to the process of step S134.

  In step S135, the central processing unit 29b reads out the information about the cooling heat shock suppression temperature Tc3 from the storage unit 29a, and sets the indoor cooling temperature Tc3 (> Tc0) as the indoor setting temperature Ts. (This process corresponds to a setting change from the automatic operation set temperature Tc0 at the time ts3 of FIG. 9 to the cooling heat shock suppression temperature Tc3 for leaving the room).

  In step S136, the central processing unit 29b determines whether or not a person non-detection signal is received from the person detection unit 35d in the communication unit 29c. Here, when the central processing calculation unit 29b determines that the communication unit 29c has received a human non-detection signal from the human detection unit 35d, the central processing calculation unit 29b proceeds to the process of step S137. On the other hand, when the central processing calculation unit 29b determines that the communication unit 29c has not received a human non-detection signal from the human detection unit 35d, the central processing calculation unit 29b ends the processing.

  In step S137, the central processing unit 29b receives the current outside air temperature To from the outside air temperature detector 25 and reads the reference outside air temperature Ta1 (first control reference value) from the storage unit 29a. It is determined whether To is greater than the reference outside air temperature Ta1. Here, when the central processing calculation unit 29b determines that the outside air temperature To is higher than the reference outside air temperature Ta1, the central processing calculation unit 29b proceeds to the process of step S138. On the other hand, when the central processing calculation unit 29b determines that the outside air temperature To is equal to or lower than the reference outside air temperature Ta1, the central processing calculation unit 29b returns to the process of step S136.

  In step S138, the central processing unit 29b reads the information on the cooling air heat shock suppression temperature Tc6 from the storage unit 29a, and sets the indoor set temperature Ts6 to the indoor cooling heat shock suppression temperature Tc6 (> Tc3). (This process corresponds to a setting change from the room cooling cooling heat shock suppression temperature Tc3 to the room cooling cooling heat shock suppression temperature Tc6 at times t6 and t5 ′ in FIG. 9. The central processing calculation unit 29b When the process of S137 is executed at time t5 when To ≦ Ta1, the room set temperature Ts is set to the entrance cooling heat shock suppression temperature Tc6 (> Tc3) at time t6 when To> Ta1. On the other hand, when the central processing unit 29b executes the process of S137 at time t5 ′ where To> Ta1. Immediately set the indoor set temperature Ts to entry for cooling during the heat shock suppression temperature Tc6.).

  In step S139, the central processing unit 29b determines whether or not a human detection signal is received from the human detection unit 35d in the communication unit 29c. Here, when the central processing calculation unit 29b determines that the communication unit 29c has received a human detection signal from the human detection unit 35d, the central processing calculation unit 29b proceeds to the process of step S140. On the other hand, when the central processing calculation unit 29b determines that the human detection signal is not received from the human detection unit 35d in the communication unit 29c, the central processing calculation unit 29b returns to the process of step S139.

  In step S140, the central processing unit 29b receives the outdoor temperature To and the indoor temperature Ti at that time from the outdoor temperature detector 25 and the indoor temperature detector 37, respectively, and at the same time, receives the third reference temperature difference ΔTr3 (first) from the storage unit 29a. (4 control reference value) is read out, whether or not the value obtained by subtracting the room temperature Ti (which may be the cooling heat shock suppression temperature Tc6) from the outside air temperature To is greater than the third reference temperature difference ΔTr3 Determine whether. Here, when the central processing calculation unit 29b determines that the value obtained by subtracting the room temperature Ti from the outside air temperature To is larger than the third reference temperature difference ΔTr3, the central processing calculation unit 29b proceeds to the process of step S141. On the other hand, when the central processing calculation unit 29b determines that the value obtained by subtracting the room temperature Ti from the outside air temperature To is equal to or smaller than the third reference temperature difference ΔTr3, the central processing calculation unit 29b proceeds to the process of step S142.

  In step S141, the central processing unit 29b reads information on the first cooling intermediate temperature Tc5, the second cooling intermediate temperature Tc4, and the exiting cooling heat shock suppression temperature Tc3 from the storage unit 29a, and sets the indoor set temperature Ts. Through the first cooling intermediate temperature Tc5 (<Tc6) and the second cooling intermediate temperature Tc4 (<Tc5) in order from the entrance cooling heat shock suppression temperature Tc6 (<Tc4). (This process is for exiting from the entrance cooling air temperature heat shock suppression temperature Tc6 after the time t7 in FIG. 9 through the first air conditioning intermediate temperature Tc5 and the second air conditioning intermediate temperature Tc4. This corresponds to a stepwise change in the indoor set temperature Ts (see the solid line) to the cooling heat shock suppression temperature Tc0. 9 shows a temporal transition of the indoor set temperature Ts in a state in which a person is continuously detected by the human detection unit 35d, in this case, of course, the indoor set temperature Ts is as shown in FIG. After the time ts3, the heat shock suppression temperature Tc3 during the cooling for leaving the room remains.) At this time, the central processing unit 29b expands the compressor 12 and the expansion unit via the communication unit 29c so that the output value of the room temperature detector 37 approaches the room set temperature Ts so that the room temperature becomes the room set temperature Ts. A control signal is transmitted to the machine 15 or the like.

  In step S142, the central processing unit 29b reads out the information about the cooling heat shock suppression temperature Tc3 from the storage unit 29a, and sets the indoor set temperature Ts from the entry cooling heat shock suppression temperature Tc6 to the exit cooling heat. The setting is changed to the shock suppression temperature Tc3 (Note that this processing is performed by changing the indoor set temperature Ts from the entrance cooling heat shock suppression temperature Tc6 to the exit cooling air heat shock suppression temperature Tc3 at time t7 ′ in FIG. 9 ( Equivalent to the single-point short chain line part)). At this time, the central processing unit 29b expands the compressor 12 and the expansion unit via the communication unit 29c so that the output value of the room temperature detector 37 approaches the room set temperature Ts so that the room temperature becomes the room set temperature Ts. A control signal is transmitted to the machine 15 or the like.

  In step S151, the central processing unit 29b reads information on the operation mode at that time from the storage unit 29a, and determines whether or not the operation mode is the heating mode. Here, when the central processing calculation unit 29b determines that the operation mode is the heating mode, the central processing calculation unit 29b proceeds to the process of the next step. On the other hand, when the central processing calculation unit 29b determines that the operation mode is not the heating mode, the central processing calculation unit 29b ends the processing. The flow after the next step is the same as the flow from step S133 onward in FIG. 8 to END. However, in this flow, “To-Ti> ΔTr3?” In step S140 is replaced with “Ti-To> ΔTr4?”, And “Tc0”, “Tc3”, “Tc4”, “Tc5”, “Tc5” in the other steps. “Tc6” is replaced with “Tw0”, “Tw3”, and “Tw6”, respectively. In such a case, the relationship of Tw0> Tw3> Tw4> Tw5> Tw6 is established.

<Characteristics of the air conditioner according to the third embodiment>
(1)
In the air conditioner according to the present embodiment, after the automatic operation button of the remote controller 50 is pressed by the user, the person detection unit 35d determines that a person is present and the outside air temperature To is higher than the reference outside air temperature Ta1. If larger, the central processing unit 29b executes heat shock suppression control. For this reason, the air conditioner 1 can execute the heat shock suppression control only when the outside air temperature To is remarkably high or low, as well as performing the heat shock suppression control according to the user's intention.

(2)
In the air conditioner according to the present embodiment, when the automatic operation button of the remote controller 50 is pressed by the user, the indoor set temperature Ts is set to the automatic operation set temperature Tc0, and the count time t of the timer 29d is set to the third reference. When the time ts3 is reached, the indoor set temperature Ts is set to the exiting cooling heat shock suppression temperature Tc3 (> Tc0). For this reason, in this air conditioner 1, not only a heat shock suppression measure when a person re-enters but also a heat shock suppression measure when a person leaves can be performed.

-Fourth embodiment-
The air conditioner according to the fourth embodiment is different from the air conditioner according to the third embodiment in the aspect of heat shock suppression control. For this reason, about the air conditioner concerning this Embodiment, only heat shock suppression control is demonstrated.

<Heat shock suppression control>
The flowchart of the heat shock suppression control according to the present embodiment is the same except for step S137 in FIG. For this reason, the detailed description about the process of each step other than step S137 is abbreviate | omitted.

  In the flowchart of the heat shock suppression control according to the present embodiment, the process of the next step is executed instead of step S137 of FIG.

  After the central processing unit 29b receives the outdoor temperature To and the indoor temperature Ti at that time from the outdoor temperature detector 25 and the indoor temperature detector 37, respectively, and reads the fifth reference temperature difference ΔTr5 from the storage unit 29a, It is determined whether or not a value obtained by subtracting the indoor temperature Ti (which may be the cooling heat shock suppression temperature Tc3) from the outside air temperature To is greater than the fifth reference temperature difference ΔTr5. If the central processing unit 29b determines that the value obtained by subtracting the room temperature Ti from the outside air temperature To is greater than the fifth reference temperature difference ΔTr5, the central processing unit 29b proceeds to the process of step S138. On the other hand, when the central processing calculation unit 29b determines that the value obtained by subtracting the room temperature Ti from the outside air temperature To is equal to or smaller than the fifth reference temperature difference ΔTr5, the central processing calculation unit 29b returns to the process of step S137.

<Characteristics of the air conditioner according to the fourth embodiment>
In the air conditioner according to the present embodiment, when the value obtained by subtracting the room temperature Ti from the outside air temperature To is larger than the fifth reference temperature difference ΔTr5, the central processing unit 29b executes the heat shock suppression control. For this reason, the air conditioner 1 can execute the heat shock suppression control only when the difference between the outside air temperature To and the room temperature Ti is extremely high or low.

-Fifth embodiment-
The air conditioner according to the fifth embodiment is different from the air conditioner according to the third embodiment in the aspect of heat shock suppression control. For this reason, about the air conditioner concerning this Embodiment, only heat shock suppression control is demonstrated.

<Heat shock suppression control>
The flowchart of the heat shock suppression control according to the present embodiment is as follows: (i) Step S121 and Step S122 in FIG. 7 are inserted between Step S136 and Step S137 in FIG. 8 is the same except that step S139 is replaced by step S104, step S123, and step S124 in FIG. Below, the specific aspect of said (i) and (ii) is demonstrated.

(1) Specific Mode of (i) First, in step S136, when the central processing calculation unit 29b determines that the communication unit 29c has received a human non-detection signal from the human detection unit 35d, the central processing calculation unit 29b Advances to the processing of step S121 and step S122 of FIG. Next, when the central processing calculation unit 29b determines in step S122 that the count time t has reached the first reference time ts1, the central processing calculation unit 29b proceeds to the process of step S137. On the other hand, when the central processing calculation unit 29b determines that the count time t has not reached the first reference time ts1, the central processing calculation unit 29b returns to the process of step S122. In step S137, when the central processing unit 29b determines that the outside air temperature To is higher than the reference outside air temperature Ta1, the central processing unit 29b proceeds to the process of step S138. On the other hand, when the central processing calculation unit 29b determines that the outside air temperature To is equal to or lower than the reference outside air temperature Ta1, the central processing calculation unit 29b returns to the process of step S137.

(2) Specific Mode of (ii) First, when the process of step S138 is completed, the process of step S104 is executed. In step S104, when the central processing calculation unit 29b determines that the communication unit 29c has received a human detection signal from the human detection unit 35d, the central processing calculation unit 29b proceeds to the process of step S140. On the other hand, when the central processing calculation unit 29b determines that the human detection signal is not received from the human detection unit 35d in the communication unit 29c, the central processing calculation unit 29b proceeds to the process of step S123. Next, when the central processing calculation unit 29b determines in step S123 that the count time t has reached the second reference time ts2, the central processing calculation unit 29b proceeds to the process of step S124. On the other hand, when the central processing calculation unit 29b determines that the count time t has not reached the second reference time ts2, the central processing calculation unit 29b returns to the process of step S104. In step S124, the central processing unit 29b sets the compressor 12, the four-way switching valve 13, the expander 15, the outdoor blower 16, and the room via the communication unit 29c so that the air conditioner 1 is stopped. A control signal is transmitted to the inner blower 34, the flap 36, and the like.

-Sixth embodiment-
In the air conditioner according to the sixth embodiment, when the heat shock suppression countermeasure button is provided in the remote controller in addition to the automatic operation button, and the user presses the heat shock suppression countermeasure button of the remote controller 50, FIG. 8 is different from the air conditioner 1 according to the third embodiment in that a series of processes according to the flowchart of FIG. The present embodiment can also be applied to the fourth and fifth embodiments.
<Characteristics of the air conditioner according to the sixth embodiment>
In the air conditioner according to the present embodiment, a heat shock suppression button is provided on the remote controller. For this reason, the user can consciously take a heat shock suppression measure.

-Seventh embodiment-
In the air conditioner according to the seventh embodiment, the indoor set temperature Ts is not fixedly set to the cooling heat shock suppression temperature Tc1 in step S103 in the flowchart of FIG. 4, but the indoor set temperature Ts. Is different from the air conditioner 1 according to the first embodiment in that it is sequentially changed so as to have a certain width with the outside air temperature To. Such an aspect can also be applied to the second to sixth embodiments.

  In this air conditioner, the temperature difference becomes constant and energy saving is realized whenever a person re-enters the room. For this reason, while being able to reduce the influence of a heat shock more, it can contribute to preservation of the global environment.

-Eighth embodiment-
In the air conditioner according to the eighth embodiment, the indoor set temperature Ts is not set in one step to the entrance cooling air temperature heat shock suppression temperature Tc1 in step S103 in the flowchart of FIG. Is different from the air conditioner 1 according to the first embodiment in that it is set in multiple stages up to the heat shock suppression temperature Tc1 during cooling for entering the room. Such an aspect is also applicable to the second to seventh embodiments.

-Ninth embodiment-
The air conditioner 1 according to the first embodiment is that the air conditioner according to the ninth embodiment is not a separate type but an integrated type air conditioner (for example, a floor-mounted type or a window frame mounting type). Is different. Such an aspect is also applicable to the second to eighth embodiments.

-Tenth embodiment-
The air conditioner according to the tenth embodiment is not a heat pump type but a different type (a heater type heater, a gas heater, an oil heater, etc. if it is a heater, a gas air conditioner, etc. if it is an air conditioner) This is different from the air conditioner 1 according to the first embodiment. Such an aspect is also applicable to the second to ninth embodiments.

-Eleventh embodiment-
The eleventh embodiment includes the air conditioner according to the first to tenth embodiments and portable terminals (hereinafter referred to as “external information devices”) such as indoor and outdoor servers, smart home appliances, and smartphones. It is different from the first embodiment in that it relates to the air conditioning system configured. In such a case, the external information device is communicatively connected to the control unit 60 of the air conditioner, and executes heat shock suppression control in cooperation with the control unit 60. For example, the external information device may remotely control the air conditioning mechanism 2 via the control unit 60, or the external information device has control parameter information, and the control parameter information is controlled from the external information device. You may make it provide to the part 60. FIG. In such a case, the external information device may be always connected to the air conditioner.

-Twelfth embodiment-
The twelfth embodiment is a first embodiment in that it relates to an air conditioner according to the first to eleventh embodiments and at least one humidity controller of a humidifier and a dehumidifier. It is different from the form.

  Here, the humidity controller may be incorporated in the air conditioner according to the first to eleventh embodiments, or according to the first to eleventh embodiments via an interlock controller, an interlock control program, or the like. The air conditioner may be connected for communication. In such a case, not only the indoor temperature Ti is controlled by the air conditioners according to the first to eleventh embodiments, but also the indoor humidity is controlled by the humidity controller. The indoor humidity control logic is the same as the indoor temperature control logic in the first to eighth embodiments. In such a case, at least the sensory temperature defined by temperature and humidity, the discomfort index, and the PMV value may be used. Furthermore, in such a case, information such as outside air humidity may be collected from a server of a government agency such as the Japan Meteorological Agency via the Internet or the like.

-Other application examples-
The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims. For example, in the present embodiment, the present invention has been described with an air conditioner capable of cooling and heating, but those related to cooling operation can be applied to a dedicated cooling device, and those related to heating operation can be applied to a heating dedicated device. Can be applied.

1: Air conditioner 2: Air conditioning mechanism 25: Outside air temperature detector (outside air environment information acquisition unit)
29a: Storage unit (first information storage unit, eleventh information storage unit)
29d: Timer (time measuring unit)
35d: human detection unit (existence determination unit)
37: Indoor temperature detector (indoor environment information acquisition unit)
50: Remote controller ( operation mode selection section)
60: Control unit t: Count time (elapsed time )
T i: Indoor temperature (indoor environment index value)
To: outside air temperature (outside air environment index value)
Tr1: First reference temperature difference ( first control reference value , eleventh control reference value )
Tr2: second reference temperature difference ( first control reference value , eleventh control reference value )
Tr3: third reference temperature difference ( first control reference value , eleventh control reference value )

Claims (4)

An air conditioning mechanism,
A presence / absence judging unit for judging the presence / absence of an object;
An indoor environment information acquisition unit for acquiring information on indoor environment index values;
An outside air environment information acquisition unit for acquiring information on an outside air environment index value;
A first information storage unit for storing information of the first control reference value;
A first control that controls the air conditioning mechanism so that the indoor environment index value approaches the outside air environment index value at any time after the time when the presence determination unit determines that the object is absent. And the difference between the outdoor air environment index value and the indoor environment index value is larger than the first control reference value in a state where the presence / absence determining unit determines that the object is present during the first control. A controller that executes a second control for controlling the air-conditioning mechanism so that the indoor environment index value is gradually stepped away from the outside air environment index value . An air conditioning mechanism,
A presence / absence judging unit for judging the presence / absence of an object;
An indoor environment information acquisition unit for acquiring information on indoor environment index values;
An outside air environment information acquisition unit for acquiring information on an outside air environment index value;
An operation mode selection section for selecting an operation mode;
A third control is performed to control the air conditioning mechanism so that the indoor environment index value approaches the outside air environment index value at any time after the specific operation mode is selected by the operation mode selection unit. In addition, when the presence / absence determining unit determines that the object is absent, a fourth control is performed to control the air conditioning mechanism so that the indoor environment index value is further brought closer to the outside air environment index value. With control
An air conditioner. An air conditioning mechanism,
A presence / absence judging unit for judging the presence / absence of an object;
An indoor environment information acquisition unit for acquiring information on indoor environment index values;
An outside air environment information acquisition unit for acquiring information on an outside air environment index value;
An eleventh information storage unit for storing information on an eleventh control reference value;
An eleventh control that controls the air conditioning mechanism so that the indoor environment index value approaches the outside air environment index value at any time after the time when the presence determination unit determines that the object is absent. And the difference between the outdoor air environment index value and the indoor environment index value is larger than the eleventh control reference value in a state where the presence / absence determining unit determines that the object is present during the eleventh control. A control unit that executes a twelfth control for controlling the air conditioning mechanism so that the indoor environment index value is stepped away from the outside air environment index value stepwise . An air conditioning mechanism,
A presence / absence judging unit for judging the presence / absence of an object;
An indoor environment information acquisition unit for acquiring information on indoor environment index values;
An outside air environment information acquisition unit for acquiring information on an outside air environment index value;
An operation mode selection section for selecting an operation mode;
A thirteenth control is executed to control the air conditioning mechanism so that the indoor environment index value approaches the outside air environment index value at any time after the specific operation mode is selected by the operation mode selection unit. In addition, when the presence / absence determining unit determines that the object is absent, the fourteenth control is performed to control the air conditioning mechanism so that the indoor environment index value is further brought closer to the outside air environment index value. With control
An air conditioning system comprising:

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